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The mentors listed below are in alphabetical order, and you can use the links to locate them by last name.
 

A |B |C |D |E |F |G |H |I |J |K |L |M |N |O |P |Q |R |S |T |U |V |W |X |Y |Z

A

Nina M. Agabian, Ph.D.
 

Microbial Pathogenesis  

"Organisms which cause chronic disease have a unique relationship with their environment. Whether a parasite, such as an African trypanosome, or an opportunistic pathogen, like  Candida albicans,  each must evolve strategies for their persistence, transmission and replication in either an immunocompetent or immunocompromised host. Moreover, the pattern of gene expression can vary significantly in the different microenvironments provided by specific tissue and organ systems. Our laboratory is interested in discovering and investigating the underlying mechanisms of pathogenesis for both protozoan and fungal pathogens at the molecular and genetic level. Most recently we have been using the genomic sequence derived for the fungus,  Candida albicans  to develop DNA microarrays which will allow genome-wide expression analysis. For the first time we are able to look at the interrelationships between genes and biological pathways and to determine the patterns of gene expression in different disease presentations, at lesions in different host tissues and to compare the human disease with that replicated in relevant animal models. This technology is being applied to the characterization of virulence factors and mechanisms of pathogenesis for this opportunistic pathogen."

Tamara Alliston, PhD

One in three American adults suffers from arthritis symptoms, yet the molecular basis of this degenerative skeletal disease remains unclear.  Our research focuses on the molecular pathways controlling mesenchymal stem cell differentiation, how these pathways function in normal skeletal tissue, and how they can be harnessed to repair tissue damaged in degenerative skeletal disease.  To answer these questions, we combine molecular, cellular, physiological, and materials science approaches.  I believe this interdisciplinary strategy will lead to the identification of targets to prevent skeletal disease or to improve skeletal repair. 
A current focus is to understand the mechanisms by which TGF-beta regulates osteoblast and chondrocyte differentiation.  Cell-based studies are used to identify signaling pathways and transcription factors downstream of TGF-beta.  In vivo studies allow examination of the role of these pathways in bone and cartilage.  A key goal of this work is to understand the control of skeletal matrix formation and quality. 
 
Gary Armitage, D.D.S., M.S.
 

"My current research interests include the development and testing of new methods for the diagnosis and treatment of periodontal diseases. Ongoing studies include evaluation of (1) microbial diversity in the subgingival flora, utilizing 16S ribosomal RNA gene detection techniques (in collaboration with Drs. David Relman and Paul Lepp of Stanford University); (2) salivary sialyl Lewis X in risk assessment for periodontal disease (in collaboration with Drs. Susan Fisher and Akraporn Prakobphol); (3) the effects of bisphosphonates and parathyroid hormone on mandibular bone density (in collaboration with Drs. Nancy Lane, Department of Medicine, School of Medicine, and Sharmila Majumdar, Department of Radiology, School of Medicine); (4) genetic tests for susceptibility to periodontal infections; and (5) drug-delivery systems for the treatment of periodontitis.

Research techniques routinely employed include (1) clinical research methods for the collection and analysis of periodontal examination findings; (2) gingival crevicular fluid analyses; (3) periodontal microbiology techniques such as the collection of subgingival plaque samples for microscopic, cultural, and molecular analyses; and (4) clinical trials and research study design."

B

Diane L. Barber, Ph.D.  

"Our laboratory uses genetic and biochemical approaches to study the signal transduction pathways used by hormone and growth factor receptors in regulating cell growth. Our recent focus is on receptor regulation of the GTPase family of proteins that control the organization of the actin cytoskeleton. Dynamic changes in the actin cytoskeleton play a critical role in cell growth and differentiation, and we have determined that these dynamic changes are regulated by a complex interplay between adhesion molecules of the integrin receptor family, members of the Rho family of GTPases, and plasma membrane ion exchangers. Most interesting is the novel observation that the link between adhesion receptors and cytoskeletal organization requires selective members of the family of plasma membrane Na-H ion exchangers. We found that Na-H exchangers are structurally linked to the actin cytoskeleton through their direct association with ERM proteins of the protein 4.1 superfamily of actin-binding proteins. Hence, plasma membrane ion exchangers can link the actin network to the plasma membrane and thereby convey input from adhesion molecules and GTPase signaling networks to the output of cytoskeletal reorganization. The functional significance of this interplay between integrin receptors, Rho family GTPases, and plasma membrane ion exchangers in cell contractility, migration, and proliferation is currently being investigated." 
 Lab web site

Charles N. Bertolami, D.D.S., D.Med.Sc.  

C

Darren P. Cox, DDS, MBA   Oral pathology

D

Caroline H. Damsky, Ph.D.
 

"Our research is directed toward understanding the roles of adhesion receptors, primarily integrins, in regulating cell survival, tissue remodeling and morphogenesis. In our studies of cell survival, we have investigated the role of the integrin-activated focal adhesion kinase (FAK) in regulating cell migration and survival. Using cells isolated from FAK-null ES cells or embryos, we have shown that FAK is required for survival following serum withdrawal. By comparing the survival of cell lines that contain wildtype or mutated p53, we have also determined that survival signals from matrix transduced by integrins and FAK, suppress a p53-regulated apoptotic pathway (Ilic et al, J. Cell Biol. 1998; Almeida et al., J.Cell Biol. 2000).

In studies related to tissue remodeling, in collaboration with Zena Werb, we have shown that different integrins transduce signals that can either stimulate or suppress matrix metalloproteinase (MMP) genes in response to degradation fragments of the extracellular matrix (Werb et al., 1989; Huhtala et al., 1995). Thus, in a tumor or chronic remodeling environment, we propose that the presence of degraded ECM can stimulate further elevation of proteinase expression, thereby exacerbating tissue degradation and contributing to disease (metastasis, arthritis) progression. We are currently testing this hypothesis by expressing bioactive fragments of the ECM component, fibronectin in osteoblasts of transgenic mice.

In studies of the role of adhesion receptors in morphogenesis, in collaboration with Susan Fisher, we have determined that human cytotrophoblast cells (CTB) adopt an vasculogenic phenotype during their differentiation and invasion of the uterine wall and maternal vasculature. As they differentiate and target maternal spiral arterioles, they adopt the complete repertoire of endothelial adhesion molecules and express receptors for vasculogenic and angiogenic growth factors. Thus, it appears that a vasculogenesis program is turned on in the trophoblast lineage as well as in the endothelial lineage (Damsky and Fisher, Curr. Opin. .Cell Biol., 1998)). 

Additional studies of integrin function address the role of integrin-ECM interactions and downstream signaling by FAK in invasion (Ilic et al., Am. J. Pathol., 2001), vasculogenesis and angiogenesis (Ilic et al., Circ. Res., 2003), and osteoblast differentiation.  In the latter case, we have established an important role for fibronectin-integrin interactions in regulating terminal differentiation of osteoblasts (Moursi et al., J. Cell Sci. 1996, 1997), and survival of mature osteoblasts (Globus et al., J. Cell Sci. 1998). These results are being tested by establishing transgenic mouse lines that express mutated integrins specifically in osteoblasts. In our transgenic lines, expression of a truncated integrin beta 1 subunit leads to disorganized bone matrix deposition and excessive remodeling by osteoclasts (Zimmerman et al., Dev. Biol., 2000).  Currently, we are developing animal models with osteoblast-specific knockout of FAK and integrin beta 1.

Thus, we work in a variety of systems with the goal of understanding how integrins and other adhesion receptors participate in the regulation of complex cellular functions."

"The focus of research in my laboratory is in the biomineralization of tooth enamel and dentin. We currently have several active projects to study various aspects of enamel and dentin biomineralization. One of these projects aims to determine the mechanism by which fluoride affects enamel formation to result in enamel fluorosis. In this project we are investigating several possible mechanisms by which enamel fluorosis occurs, including altered protein/mineral interactions, and a direct of fluoride on the developing ameloblasts. 

In order to determine factors that alter enamel formation, we need to better understand the proteins, proteinases and other molecules responsible for normal enamel formation. We are using immunopertrubation and antisense methods in tooth organ culture to alter the presence of certain proteins in enamel development. These studies have suggested that the enamel matrix protein, ameloblastin, has a key role in the regulation of enamel matrix synthesis.

Our studies on dentin formation have utilized various available transgenic mouse models with transgene expression driven by the osteocalcin promotor. In one of these mice models that over expresses TGF- , the dentin mineral apposition rate is increased while the physical properties of the dentin remain the same. Studies of dentin formation in these various transgenic mouse models will allow us to determine the key elements in dentin biomineralization and to use these elements to form dentin-like materials  in vitro ."
 

Rik M. Derynck, Ph.D.
 

"Our research focuses on the role of transforming growth factors- and  , two structurally unrelated growth and differentiation factors, in mesenchymal and epithelial cells. We use molecular, genetic cell biological and biochemical approaches to address several cell physiological and developmental questions. The work has direct relevance to many questions in orofacial development and healing and is therefore of value to the proposed NRSA.

TGF- is a growth factor for many cell types of non-hematopoietic origin and exerts its functions in an autocrine/paracrine fashion mainly in normal epithelia and in solid tumor development. It is present as a transmembrane protein at the cell surface, from which the ecodomain can be proteolytically released as a secreted polypeptide. The transmembrane form of TGF- functions as a growth factor involved in cell-cell communication. Our major projects focus on the role of the cytoplasmic domain. We specifically study its ability to interact with cytoplasmic proteins that constitute an associated protein kinase complex and its potential role as a signaling entity, as well as its function in cell physiology and development.

TGF- is a growth and differentiation factor which induces growth arrest in epithelial cells, yet stimulates proliferation in mesenchymal cells, and furthermore, is a potent inducer of extracellular matrix deposition and integrin expression. TGF- is a prototype factor for the many related differentiation factors in the TGF- superfamily. Two major lines of research are followed. In one large project, we address the mechanism of signaling of the TGF- receptors, which are transmembrane serine/threonine kinases. In the other major project, we study the role of TGF- and vgr-1, a related factor, in mesenchymal differentiation, specifically in differentiation into the muscle, bone and cartilage lineages. These developmental questions are approached in cell culture and  in vivo , including transgenic models."
Lab web site

E   

F

John D.B. Featherstone, M.Sc., Ph.D.  

"I am currently involved in research in the following fields:

1. Effects of Lasers on Dental Hard Tissues
The overall objective of this research is to provide fundamental information about the effects of laser light on dental hard tissues (enamel and dentin of the teeth) in order to develop means of using lasers to a) detect early decay, b) treat teeth and modify the mineral for the prevention of the progression of dental decay.

2. Management of Dental Decay by Risk Assessment
These studies involve the application of microbiological and chemical assays of saliva as part of a risk assessment scheme to enable the management of dental decay by prevention and conservative treatment rather than conventional physical removal of decay and placement of restorations (fillings).

3. Biological mineral and protein interactions
Biological mineral is a defective calcium phosphate crystalline material.  Studies of protein/mineral interactions are in progress to understand the processes of biomineralization.

Susan J. Fisher, Ph.D.
 

"Our major area of investigation is understanding adherence mechanisms used by microbial pathogens. In one project we are testing the hypothesis that bacteria which colonize the oral cavity do so by interacting with the carbohydrate portions of salivary receptors. In general, we use whole-cell ligand blotting (overlaying blots of salivary glycoproteins with bacteria) to identify interactions between individual salivary molecules and particular bacterial species. This technique led to the identification of a highly glycosylated, proline-rich glycoprotein (PRG) as the major Fusobacterium nucleatum receptor in saliva. We then determined, using mass spectrometry and nuclear magnetic resonance spectroscopy, the complete structure of the subset of PRG oligosaccharides that carry the bacterial receptor activity. We used this same experimental strategy to study the interaction between streptococci and the low-molecular-weight salivary mucin. Very recently we showed that this glycoprotein carries sulfated sialyl Lex structures and is a ligand for L-selectin. This observation has interesting implications for leukocyte trafficking in the oral cavity."
 

Daniel Fried Ph.D.
 

"Optical or photonics based methods are playing an increasingly important role in medicine and dentistry by providing a means of minimally invasive diagnostics and imaging without the use of ionizing radiation. Projects include: the use of optical diagnostic tools such as optical coherence tomographic imaging, Raman scattering, IR and fluorescence imaging, and time-resolved photothermal radiometry. In order to use lasers and optical diagnostic tools safely and effectively it is important to characterize the optical properties of the tissue at the wavelengths of interest. Therefore, a major emphasis of my research has been on the accurate elucidation of those properties."
 

G
 

Stuart Gansky, Dr.P.H.
 

Stuart Gansky's research has concentrated on collaborative oral health research areas and its related methodological issues. Collaborative research projects have included a series of studies examining dentin, bonding, and tissue engineering; the Intergenerational Study of Adult Periodontitis (MultiPied); the Study of Chronic Pain/Temporomandibular Disorders (TMDs) in Young Women; caries risk assessment studies (one on early childhood caries and one on high risk adults); and tobacco cessation interventions.

He currently serves as Associate Director of the Biostatistics and Research Design Core of UCSF's Comprehensive Oral Health Research Center of Discovery as well as Director of the Measurement & Evaluation Core of UCSF's Center to Address Disparities in Children's Oral Health. He is PI of an NIDCR grant to develop risk assessment models for early childhood caries.  Also, he is co-PI and biostatistician to study factors related to temporomandibular joint disorders and fibromylagia precursors in an established cohort of young women in which racial differences in pain reports have been found.
 

Barbara Gerbert, Ph.D
 

Dr. Gerbert has focused her research on the barriers to optimal preventive health care and the role of health care professionals. The research emphasizes the role of oral healthcare providers and primary care physicians in providing preventive care in the changing healthcare delivery system.
 
 

Harold Goodis, D.DS.
 

"My work focuses on the interactions between neurovascular modulators and inflammatory mediators; specifically prostaglandin E 2 (PGE2 ) and bradykinin (BK). The work allows me to use bovine and rat dental pulp for data collection with superfusion, radioimmunoactivity (RIA), and various blotting techniques. These techniques allow the study of the onset of neurogenic inflammation and the pain response in relationship to the release of peptides and the effect innocuous cooling has on their elaboration. Preliminary studies indicate that the neurogenic inflammatory response is related to the release of these peptides (PGE2 , BK).

The continued work using PGE 2 /BK combinations will lead to the identification of the substances in the dental pulp that may be responsible for acute and chronic inflammatory reactions. The addition of RIA to my laboratory protocols has better define these interactions and has allowed me to identify the BK B 2 receptor in rat dental pulp. The identification of these receptors in bovine and rat pulp will lead to their identification in human pulp and lead to development of a model to further elucidate the different mechanisms involved in the formation of the BK receptors, including the BK B 1 receptor, believed to be involved in chronic inflammation and pain.  

Recent work by other investigators has shown that fluid movement through the dentin is related to dental pain, tooth sensitivity, biocompatibility of dental restorative procedures, materials, and medicaments, and the ability of restorative materials to form chemical bonds to the dentin. Following this experience, I have shown that dentin permeability in extracted teeth is extremely sensitive to storage conditions, (medium and time) and that many of the assumptions previously made need more careful consideration, as shown in my 1991 paper and several abstracts. This work is continuing and is an integral part of our funded program project grant, Dentin Characterization and Modification. The work has been expanded in a competitive renewal application to study permeability and other mechanical, physical and chemical changes occurring in in vitro transparent coronal dentin and root dentin. These studies are important as altered forms of dentin resulting in changes in dentin fluid flow and a diminishing pulp canal space may lead to an altered pain response resulting in the need for interventions not presently a part of today's techniques.  

Taken together, the above work represents a focused investigation into the biology of pain and inflammation in a unique tissue consisting of primary afferent nociceptive neurons. It affords an opportunity to develop alternative therapeutic techniques which will replace invasive, pharmacological and non-reversible treatment modalities."
 

Deborah Greenspan B.D.S, D.Sc. (Med)
 

"My areas of interest include clinical, laboratory, and epidemiological studies relating to the oral manifestations of AIDS; the oral effects of cancer therapy; and the development of new therapeutic approaches for oral mucosal and salivary gland disease. I am part of a major epidemiological study of the oral lesions of HIV infection and direct a group of investigators identifying the oral lesions and providing treatment to people with these lesions. Some current studies include the following: the prevalence, incidence, and predicators of oral lesions in women with HIV infection (as part of the Women's Interagency HIV Study -WIHS), and the changing patterns of oral disease in the era of highly active antiretroviral therapy in different HIV-positive populations. In addition, I am collaborating with Dr. Francisco Ramos-Gomez (Dept. of Growth & Development) on studies of injuries to dental heath-care workers.  

I am involved in several clinical drug trials, including the treatment of aphthous ulcers, the treatment of oral warts, and the use of antifungal medications in the treatment of oral candidaisis. In the future, I plan to continue with my work in all of these fields, to learn more about the significance of the oral lesions of HIV infection and to develop better drugs for the treatment of a variety of oral conditions, such as oral candidasis, warts, xerostomia, and aphthous ulcers."
 
 
John S. Greenspan, B.D.S., Ph.D.
 

"My main research interest centers on the etiology, pathogenesis, and management of oral soft tissue diseases, notably those associated with HIV infection and other causes if immunosuppression, as well as aphthous ulcers, Sjögren's syndrome, and oral cancer/pre-cancer.   

I serve as director of the Oral AIDS Center (OAC), which has been supported by the NIDR. The OAC continues its research on the pathogenesis of oral lesions associated with HIV infection. Dr. Joan Hilton is responsible for the epidemiology portion of the OAC. Dr. Hilton and myself, along with members of the OAC are looking at the significance of oral disease in the progression of HIV infection. We are currently examining a large cohort of women for the prevalence of oral lesions such as hairy leukoplakia, aphthous ulcers, and oral candidiasis. Dr. Joel Palefsky is leading a team research effort into the molecular pathogenesis of EBV-associated hairy leukoplakia, and Dr. Nina Agabian leads the candidiasis portion of the OAC's research program. The OAC also conducts clinical trials of agents and modalities to treat oral opportunistic infections, neoplasms, and autoimmune/idiopathic lesions of HIV infection.

I also serve as Director of the UCSF AIDS Clinical Research Center (ACRC). The mission of the ACRC is to provide clinical and scientific leadership in a multidisciplinary response to the AIDS epidemic in Northern California. Specifically, the ACRC has three main objectives:  

to facilitate the clinical care of HIV-infected persons in an academic setting, providing a research infrastructure that will enable epidemiological, clinical, behavioral, and basic research to be conducted efficiently,

to promote pilot research projects into the pathogenesis, etiology, prevention, and treatment of HIV infection and its complication, and 

to involve regional institutions and community-based organization in the overall AIDS research enterprise in order to maximize communications between scientists and care givers and to foster collaborative research with the community.  

To facilitate the meaningful exchange between University researchers and community groups, the ACRC maintains an active Community Advisory Board, whose members participate in community outreach activities and pilot grant review."
 

Carol A. Gross, Ph.D.
 

"My overall interest is to study global regulatory networks in the bacterium  E. co/i,  which is amenable to both genetic and biochemical approaches. We take two different approaches, each of which illuminates this issue from different perspectives. First, we study the heat shock response. This area of study has led us into a consideration of how the cell monitors and regulates the folding state of proteins, how proteins are targeted for degradation and how the cytoplasmic and periplasmic compartments in K  co/i  are coordinated. Second, we study RNA polymerase, the enzyme responsible for transcription, because it is the ultimate target of regulatory systems that integrate intracellular and extracellular signals by adjusting the transcriptional potential of the enzyme.  

Our study of the heat shock response has led us to find that K coli  mounts two distinct responses to heat and other stresses: (1) a response measuring conditions in the cytoplasm, which is orchestrated by the alternative sigma factor a32, and (2) a response measuring conditions in the periplasm, which is orchestrated by the alternative sigma factor aE. Each response senses protein folding as well as  other,  yet unknown signals. We have  defined the early  events occurring in the  cytoplasmic heat shock response and are now investigating the molecular mechanism of these events. We have defined many of the players in the periplasmic heat shock response and are now defining the early events in this regulatory cascade, as well as using this response as a entry point to understand how events in the periplasm and cytoplasm are coordinated.  

To understand how various cellular regulatory systems control RNA polymerase, we first delineate the functional anatomy of the enzyme and then investigate how altering its individual functions affects gene regulation. Our study of RNA polymerase has shown that the sigma subunit orchestrates initiation, that elongation and termination are coordinated events and that, as judged by genetic criteria, conserved regions of RNA polymerase contact each other. Current work in the laboratory is focused on defining the conformational changes in sigma throughout initiation, defining the sigma-core interface, investigating the role of that interface in the transcription process, and investigating the contribution of sigma affinity to global control of transcription initiation. A second focus of our work is to define the functional anatomy of core RNA polymerase by mapping interacting domains of RNA polymerase and then determining the functional significance of such interactions."

H
 

Charles Hoover, PhD

"My general research interests concern the etiology, pathogenesis, and treatment of oral microbial infections. My primary focus is the application of molecular genetic techniques to investigate these issues and the use of microbial colonization levels to monitor therapeutic interventions, as well as to assess the risk of future disease.

Presently active independent and collaborative projects include (1) development of a conjugal E. coli-Porphyromonas gingivalis  shuttle vector for use in genetic complementation (with Dr. David Corradi, Periodontology resident), (2) identification of oligosaccharide termini involved the in adherence of  Candida albicans to salivary glycoproteins (with Dr. Susan Fisher and Asfoon Barkhordar, first-year dental student and summer fellow), (3) identification of oligosaccharide termini involved in the adherence of  Helicobacter pylori  to salivary glycoproteins (with Drs. Susan Fisher and Akaporn Prakobphol), (4) assessment of the role of Bacteroides forsythus  components in bone nodule formation (with Drs. Peter Loomer and Ravi Smith, Periodontology resident), (5) evaluation of risk factors associated with the development of early childhood (baby bottle) caries (with Drs. Francisco Ramos-Gomez, Department of Growth and Development, and Stuart Gansky, Department of Dental Public Health and Hygiene), and (6) the effect of oral applications of plant-derived monoclonal anti -Streptococcus mutans  antibodies on oral recolonization by mutans streptococci (with Drs. Jane Weintraub, Department of Dental Public Health and Hygiene; Joel White, Department of Restorative Dentistry; and Keith Wykoff, Planet Biotechnology).

Future projects include (1) a study to evaluate the effectiveness of ultrasonic lavage with a chlorine dioxide mouthrinse (Cloysis II) in delaying recolonization by periodontopathic bacteria (with Drs. Robert Wirthlin; Sophia Tseng, Periodontology resident; and Perry Ratcliff, Rowpar Pharmaceuticals), (2) a study to determine the benefits of caries management by risk assessment (with Drs. John Featherstone, Department of Restorative Dentistry; Jane Weintraub; and Joel White), and (3) a study to evaluate prevention and treatment outcomes associated with early childhood caries (with Drs. Jane Weintraub, Francisco Ramos-Gomez, Stuart Gansky, and John Featherstone)."

Susan Hyde, DDS, MPH, PhD

Epidemiology and gerontology

I

J

Richard Jordan, D.D.S., Ph.D.

"The focus of my translational research program has been the characterization of molecular events that occur during the progression of oral precancer to oral cancer centered on how molecules, that normally regulate cell proliferation, become dysregulated and thereby contribute to the neoplastic phenotype. My research work, to date, has been the application of molecular markers to clinical biopsy material obtained from patients with oral precancer and cancer. My group was the first to characterize changes in critical cell cycle regulators including p27^kip1 and skp2 in oral precancer and cancer.  We were also the first to show differing patterns of p53 protein expression in oral precancer and to full-describe changes in the entire p53 gene in head and neck cancers and impact on radiation therapy.  We have also characterized alterations in the CDKN2A gene in oral precancer and cancer using state-of-the-art molecular pathology methods such as laser capture microdissection (LCM) and real-time, reverse transcriptase PCR.  We were also the first group to define changes in a key regulator of the p53 tumor suppressor gene, p14^ARF in the development of oral cancer.  Another similar area of investigation has been the application of these studies to chronobiology, the study of biological events over 24 hours, where we have demonstrated a circadian pattern in oral epithelial proliferation and the expression of cyclin proteins and clock genes."

www.ucsf.edu/oralpath

K  

Arnold Kahn, Ph.D.

"For about the past 150 years, the number of 65 year old + individuals in the United States and the advanced countries of the world has steadily and dramatically increased meaning that more and more individuals are now experiencing the diseases and disorders commonly associated with old age. These diseases/disorders include but are not limited to osteoporosis, osteoarthritis, hearing loss, cataract and loss of cognitive ability. Consequently, it has become increasingly imperative to learn more about the aging process and how this process is linked to the increased incidence of a particular subset of diseases and disorders.  The ultimate goal is to use this information either to prevent these diseases/disorders from occurring or substantially delay their onset, thereby assuring “healthy aging”.  My research has three components, each at a different stage of development. The first, and most advanced of these is to identify and employ markers of the aging process found in dental hard tissue and bone. Such markers are essential to objectively determine the state of aging of experimental animals or human subjects, and to assess the efficacy of interventions that might delay or prevent old age associated-disease.  The data, to date, confirm that secondary dentin formation has utility as a measure of age in human subjects but more importantly may also provide information on systemic disease or senescent change (e.g., atherosclerosis, hypercholesterolemia).  Similarly, the loss of alveolar bone may also be a quantifiable indicator of the physiological aging process but appears to be unassociated with bone loss observed elsewhere in the aging skeleton. 

In addition to work on markers of aging, efforts are also underway to become more fully engaged in a multi-center initiative (the Longevity Consortium) aimed at identifying genes important in determining life span and the risk of old-age associated diseases/disorders in humans.  Efforts, to date, have included analyses of TGF-b polymorphisms (paper published) and alleles in the interleukin-1 gene family (MS in preparation) but future work will focus on genes in the insulin/IGF-1 pathway and involved in stress resistance. The latter work will be linked, it is hoped, to the use of computer-based simulations of metabolic pathways to better identify candidate genes for analysis in future genetic epidemiology studies and/or experiments in animal models or in vitro.  The current plan is to initiate pilot studies using the latter technology sometime in 2004." 

Ophir Klein, M.D., Ph.D.

Our research is centered on understanding and treating the processes underlying craniofacial and dental malformations. Our main focus is the use of mice as a genetic model system to elucidate the mechanisms responsible for normal and perturbed development of teeth, facial skeleton, taste papillae, and other organs. Specifically, we are interested in the role of growth factor signaling and cell-matrix interactions in the formation of orofacial structures and in the regulation of adult stem cells in teeth.

 Currently, there are two principal projects in the lab. The first is the analysis of adult stem cells in the mouse incisor. We are working to understand the capacity of dental stem cells to self-renew as well as to differentiate into the various cellular components of the tooth, such as the enamel-producing ameloblasts and dentin-producing odontoblasts. Our second main project involves the study of the mechanisms responsible for embryonic tooth development. This process, like the development of many organs, is driven by the dialogue between two tissues, the epithelium and the mesenchyme. We have shown that inactivating mutations in antagonists of FGF signaling, known as Sprouty genes, result in the presence of supernumerary teeth. Ongoing efforts in this area of investigation include genetic and biochemical approaches to the role of FGF and HH genes in tooth morphogenesis. In addition to our experiments in mice, we are collecting cohorts of patients with craniofacial and dental birth defects to identify new genes involved in these processes.

   
Randall H. Kramer, Ph.D.
 

"Our research is directed at understanding how adhesion receptors regulate cell-matrix interactions and what signals promote cell survival and growth. The first project is testing whether integrins and growth factor receptors coordinately regulate epithelial cell motility, invasion and proliferation. In addition, we are exploring the specific downstream signaling events initiated by activation of growth factor receptors that promote activation of focal adhesion kinase and integrin receptors and disrupt cadherin junctions during tissue remodeling. Finally, we have found that cadherins generate signals that promote anchorage-independent growth and suppress apoptosis.   

The second research topic concerns the laminin-binding alpha 7 integrin during skeletal and smooth muscle differentiation. The alpha 7 integrin forms the myotendinous junction and human congential myopathy is caused by mutation in the alpha 7 gene. Studies are underway using the alpha 7 gene promoter in order to understand how integrin expression is developmentally regulated. The alpha 7 integrin is alternatively spliced in its extracellular and cytoplasmic domains, and this developmentally regulated splicing controls the activation state of the integrin. The alpha 7 receptor and its variants are being characterized through molecular approaches to further define how receptor function is regulated."

John H. Kinney, PhD

Synchrotron based computed tomography and biomechanics of calcified tissues.

L

Wu Li, MD, PhD

Enamel proteins

Jon D. Levine, M.D., Ph.D.
 

"We are pursuing three major areas of research. The first area is an investigation of mechanisms that mediate transduction of painful stimuli in sensory neurons. Transduction for both thermal and mechanical stimuli are investigated and mechanisms underlying sensitization of primary afferent neurons are also studied. The second messenger systems and ionic conductances affected during sensitization are being determined. The modulation of transduction by opioids is also being investigated, including the mechanisms underlying opioid tolerance and dependence. Molecular biological, biochemical, in vitro and in vivo electrophysiological and behavioral techniques are employed. We also investigate CNS circuits that mediate analgesia. Studies of these circuits involve analysis of sites in the CNS and neurotransmitters involved. Our recent work has described novel CNS circuits that contribute to analgesia. We evaluate neural and endocrine contributions to inflammation and to the immune response. The circuits and mediators that contribute to the expression of immune responses are being analyzed. A negative feedback inhibition of the inflammatory response that involves specific neural and endocrine circuits has recently been discovered."

Peter Loomer, DMD, PhD

Bone remodelling, peridontal pathogenesis, implants

Francina Lozada-Nur, D.D.S., M.S., M.P.H.

"Currently, my research interests focuses on clinical epidemiology; media literacy and video production as a new instrument to teach oral health to children; and on the use of alternative medicine to treat chronic oral conditions such as oral lichen planus, and the burning mouth syndrome.

Clinical Epidemiology: 

I am interested in looking at the role of hepatitis C infection in the pathogenesis of oral lichen planus (OLP) as well as the role of OLP in the prognosis of HCV disease

In addition, we are evaluating the prognostic value of routine testing for mucous membrane pemphigoid and disease course.”
 

M

Mahesh Mancani, MD

My long-term research goal has been to establish an interdisciplinary program to treat patients’ bone abnormalities with cell-based therapies. Towards this end, my lab is exploring the role of bone marrow stromal cells (BMSCs) in bone formation and remodeling, focusing on ways to enhance normal bone formation in patients with bone deficits or with osteoporosis.  We are focusing on 2 areas: 1) developing techniques to engraft BMSCs and engineer bone, and 2) describing the role of BMSCs in bone formation and repair.

 One of our ongoing projects is the preparation of a Phase I clinical trial for the placement of autologous BMSCs to close calvarial bone defects in patients. Towards that end, we are investigating the interaction between BMSCs and mineral matrices at the time of transplantation.

Ralph Marcucio, PhD

“My research focuses on elucidating the molecular and cellular events that regulate development of the craniofacial complex. Currently, I am examining the molecular interactions among the forebrain, the adjacent neural crest mesenchyme, and the overlying surface ectoderm. I have demonstrated that signaling by the Sonic hedgehog pathway within the forebrain regulates the formation of an important signaling center that is located within the ectoderm covering the face. These disruptions created severe facial malformations that resemble Holoprosencephaly. This is a severe malformation sequence that affects the middle part of the upper jaw, the upper part of the face, the eyes, and the forebrain. We are currently working to determine the role of various other pathways during development of this region of the face in order to identify other signaling pathways that may be susceptible to perturbations that could create phenotypic change that relates to Holoprosencephaly. In related research, I am utilizing my knowledge as a developmental biologist to assess the mechanisms that underlie the regenerative potential that the skeleton possesses. I am studying the cellular interactions that occur at the site of a skeletal injury in order to elucidate the molecular signaling mechanisms that regulate skeletal repair.”

web site: http://orthosurg.ucsf.edu/orthotrauma/html/research_molecular.htm

Grayson W. Marshall, D.D.S., M.P.H., Ph.D.

"Currently my work is focused on structure- property relationships of calcified tissues, particularly enamel and dentin, and cementum, to improve our basic  understanding of these biological materials with respect to their mechanical behavior, and demineralization processes associated with bonding procedures and pathology. We use a variety of complimentary techniques some of which are nearly unique to our group (x-ray tomographic microscopy; atomic force microscopy (AFM); and AFM-based nanoindentation) as well as other complimentary methods including wet SEM and x-ray microanalysis. We have pioneered several of these methods for the study of calcified tissues, and dentin in particular, and used the AFM to for the first demineralization rate studies, the first nanomechanical properties studies, and have obtained high resolution non-invasive images of caries and dentin that allows the study of the three dimensional structure of caries attack on tooth structure. This work helps define alteration in properties and structure with hydration state, mineral state, and variations induced by disease and physiological processes. This information is needed to develop a composite structural model of calcified tissues and to provide fundamental information needed for tissue engineering."

Lab web site

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Sally J. Marshall, Ph.D.
 

"My research interests center on understanding the relationship between structures, properties and mechanisms in materials. My major expertise is in x-ray scattering, particularly diffraction, by materials and atomic force microscopy for microstructural and mechanical properties characterization. The nanostructure and properties of the interface between materials and calcified tissues are of great clinical significance since failure occurs in the weakest area of this structure. My current research efforts are mainly focussed in 2 areas: dentin characterization and modification, including the dentino-enamel junction, and the development of new dental implant material systems .

Much of dental materials research involves attempts to improve bonding to dentin. Through collaborative efforts with scientists at Lawrence Livermore and Lawrence Berkeley National Laboratories, we are characterizing dentin, structurally and chemically, with the premise that developing materials to bond to this substrate will be greatly hampered until the substrate is understood. We began by studying normal coronal dentin and have progressed from normal dentin to altered forms of dentin, including transparent dentin related to disease, age and intratooth position. We are using atomic force microscopy to study morphological changes in dentin as a function of drying, storage and demineralization. Demineralization is related to the caries process as well as being a critical part of preparation for bonding. The AFM is used to measure the nanoscale mechanical properties of dentin and its interface with restorative materials. These measurements are being combined with a model of dentin to predict properties on the macroscale. We use x-ray tomographic microscopy, a 3-D non-invasive imaging technique developed by a colleague at LLNL, to study morphological and mineral density changes as well. We have begun a new project that uses the DEJ as a model interface between 2 materials with different mechanical properties. We are beginning by studying the structure and using fracture mechanics to determine the mechanical properties of the DEJ.
 

My second area of interest is in the area of ceramic coatings on implants. We are working with colleagues from LBNL to develop a new apatite based bioactive coating that will more permanently adhere to Ti and Ti alloys."

Lab web site

Jeffery N. Martin, MD, MPH

My work focuses broadly in the area of infectious diseases epidemiology and specifically in the fields of human herpesvirus 8 (HHV-8) and HIV infection. In the realm of HHV-8, a primary goal is to understand the specific route of viral transmission both in non-endemic settings (such as the U.S.) and endemic settings (such as Africa). Implicit in this work is understanding viral shedding among infected persons. In this regard, saliva is now known to be the body fluid that most commonly harbors HHV-8 and hence understanding the determinants of viral shedding is a major goal. My interest in HHV-8 extends to the disease it causes, Kaposi's sarcoma, where my group's work in Africa is studying optimal approaches to treatment. In the field of HIV, I am involved in several prospective cohort studies, both in the U.S. and Africa, in which the focus is on translational research related to pathogenesis and response to treatment. In addition to my research, a considerable area of focus is on the development of clinical research training. As Director of the UCSF Training in Clinical Research (TICR) Program, I oversee curriculum development in a broad array of topics related to epidemiology and biostatistics in the context of both observational and experimental study design.

Robert Messing, MD

 My laboratory is interested in discovering new molecular strategies to modify behaviors related to substance abuse and co-morbid conditions, such as anxiety and pain.  Studies in cell culture and in model systems such as Drosophila melanogaster have identified signaling proteins important for responses to drugs of abuse.  We use gene targeting and RNA interference in rodents to understand the role of these proteins in behavior and to determine if they are targets for development of new therapeutic agents to treat addiction.  In addition, we have pursued studies with some of these proteins in stroke and Alzheimer’s disease.  

web site: http://www.galloresearch.org/site/MessingLab/

Arthur J. Miller, Ph.D.

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Joel M. Palefsky, M.D.
 

"Our ongoing projects fall into two main categories: 1) control of DNA tumor virus replication and clinical manifestations of DNA tumor virus infection in the setting of HIV-related immunosuppression, and 2) biology of DNA tumor virus-associated epithelial neoplasia.  

Human papillomavirus: My group conducts studies characterizing the natural history and pathogenesis of HPV infection and HPV-associated neoplasia in HIV+ men and women. Pathogenesis studies include investigation of cell-mediated immune response and characterization of cellular genetic changes in HPV-associated lesions.
 
We are also investigating the role of calcium regulation proteins in the immune response to HPV and HPV-induced transformation, as well as stromal growth factors and cytokines. Finally, we are investigating novel gene therapy approaches to the treatment of HPV-related neoplasia that take advantage of virus-specific gene targets.  

Epstein-Barr Virus : My program on Epstein-Barr virus, like the HPV program described above, is focused on epithelial infection. We have characterized EBV gene expression in a unique EBV-associated epithelial lesion that occurs in immunocompromised patients known as hairy leukoplakia (HL). We are characterizing expression and function of novel EBV
proteins that play a role in the pathogenesis of epithelial infection.  As in our studies of HPV, we are examining the role of calcium regulation proteins in the immune response to EBV and their effect on EBV replication."
 

Lenore P. Pereira, Ph.D.
 

"Our research has evolved from studies on herpesvirus glycoproteins, to infection of polarized epithelial cells and viral infection during pregnancy. Current projects investigate CMV infection of the placenta that functions as a site of viral infection and transmission to the fetus. We found that CMV replicates in cells of the placenta called differentiating cytotrophoblasts, impairs their invasion and downregulates key adhesion and immune molecules required for proper development. Moreover, CMV-infected endothelial cells transmit infection to placental cytotrophoblasts supporting evidence that infection small blood vessels become infected in vivo. Together these findings suggest defects in formation of hybrid fetal-maternal vasculature in the uterus could decrease blood flow to the fetus causing intrauterine growth restriction. Using microarray analyses, we are identifying viral genes that dysregulate cytotrophoblast differentiation, invasion and immune functions. We are also exploring the role of immune molecules, in particular human and viral interleukin-10 that reduce the functions of matrix metalloproteinsases. Failure of infected cells to degrade the extracellular matrix impairs endothelial cell migration and invasion of differentiating cytotrophoblasts in vitro. With regard to routes of CMV transmission to the fetus, we found that the uterus serves as a virus reservoir and that replication in the decidua correlates with transmission of infection to the adjacent placenta. Our results suggest that co-infections could elicit an inflammatory response that undermines placental development. Using PCR and immunohistochemistry, we identified CMV, herpes simplex virus and bacterial pathogens associated with premature labor are present at the maternal-fetal interface in early gestation. Current studies examine infections in this microenvironment and their involvement in pregnancy complications at midgestation, an issue of critical importance to prenatal development."

Ove A. Peters, PD Dr med dent, MS 

Until recently, my primary research interests addressed clinical questions in endodontic therapy such as effects of root canal preparation on canal geometry measured by micro CT, physical parameters of Nickel-Titanium alloy in continuously rotating root canal instruments and antimicrobial efficacy of endodontic procedures . Presently, I am developing a second line of research that builds on several projects that I was also involved with in the past and addresses some issues in neurobiology and immunology: regulation of chronic inflammation, effect of inflammatory mediators on hard tissue metabolism and diagnostic parameters of pulpitis

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Daniel Ramos, D.D.S., Ph.D.
 

"The main project in the laboratory involves evaluating the expression of tenascin-C (TN-C) during the progression of oral cancer. We have shown that TN-C is highly expressed in oral squamous cell carcinoma whereas only trace amounts can be identified adjacent to the basement membrane in normal oral mucosa. In mild to moderate dysplasia, expression of TN-C is similar to that found in the normal oral mucosa. However, in carcinoma in situ, TN-C expression is detected throughout the tissue stroma.

To examine the organization of TN-C matrices in vitro, we are using oral squamous cell carcinoma (SCC) cell lines and peritumor fibroblasts (PTF) isolated from biopsies and head and neck dissections. We have shown that several different oral cancer cell lines and PTF secrete a soluble form of TN-C, but are unable to organize a TN-C matrix in vitro. However, when co-cultured with oral SCC cells, the PTF assemble a TN-C matrix. Oral SCC cell conditioned medium does not induce the PTF to organize a TN-C matrix, but medium conditioned by both the oral SCC cells and the PTF can induce TN-C matrix organization by the PTF. TN-C matrix assembly is inhibited by antibodies to several integrin subunits as well as by antibodies to fibronectin. However, this inhibition can be reversed by first seeding the co-cultures on a pre-existing fibronectin substrate. We conclude that a fibronectin template is necessary for the SCC cell/PTF co-cultures to organize a TNC matrix, and that soluble factors secreted by both cell types are responsible for in vitro organization of TN-C matrices.

Another project in the laboratory involves the differential expression of v integrins by highly and poorly metastatic murine melanoma cells. We have found high expression of the v 3 complex in the highly metastatic melanoma cells, but no expression of the v 5 complex. In contrast, the poorly metastatic cells express high levels of the v 5 complex, with no expression of the v 3 complex. We are currently evaluating how expression of 3 in the nonmetastatic cells affects invasion and metastasis."
 

Francisco Ramos-Gomez, D.D.S. M.Sc., M.P.H.
 

"Dr. Ramos's research focus is the surveillance and epidemiology of "children at risk". His clinical research concentrates on HIV-infected and immunocompromised children; very young children affected by caries; children suffering from abuse; and children who are underserved or who lack adequate access to oral health care services. He seeks to increase understanding of how the knowledge, attitudes, and behaviors of patients, their families, and their health-care providers affect health-care practices. These investigations are designed to determine predictor variables and prognostic indicators for specific health-care risk factors confronting children at risk, and to use these predictors to devise ways in which the dental health care community can make early diagnosis of problems faced by these children. This work is intended to lead to the introduction of prevention or effective intervention and early treatment measures, with the purpose of improving the quality of life for these young patients. 

Dr. Ramos has made a number of contributions within this field, addressing topics such as the diagnosis, significance, and management of HIV-related orofacial soft-tissue manifestations in children; indicators for the early identification and effective treatment of children at risk for caries; prevalence and treatment costs of nursing caries among children in Northern California; the knowledge and behavior patterns of California dentists regarding child abuse and neglect; and accidental injuries among dental health-care workers. He is currently involved in research on the prevalence and treatment of early childhood caries; the oral risks factors faced by immunocompromised children affected by AIDS; and caries patterns among Latino pediatric populations in the United States and Mexico. "
 

John L. Rubenstein, M.D., Ph.D.
 

Genetic Regulation of Head Development

"The embryonic neural tube differentiates into diverse structures depending upon their spatial coordinates within the embryo. The forebrain, which is at the rostral end of the neural tube, differentiates into the cerebral cortex, the basal ganglia and other components, each with distinct histologies and functions. The genetic program which specifies the developmental fate of different regions of the neural tube remains to be elucidated.  

Our laboratory is interested in studying the genes that regulate regional specification and differentiation of the mammalian forebrain. In addition we are interested in the genetic control of craniofacial development. To this end, we have identified several novel genes that are candidates for regulating forebrain and craniofacial development. We are focusing on two types of transcription factors. One, named Tbr-1, encodes a homologue of Brachyury, that is expressed in the cerebral cortex, while the other, named Dlx, encodes a homeodomain that is expressed in craniofacial primordia and in the basal ganglia.   

Analysis of the expression of these and related genes has proven to be a useful method to define subdivisions of the forebrain. These studies have led us to propose that the forebrain is subdivided by longitudinal and transverse boundaries, and thereby has a neuromeric organization. We are continuing these studies studying the inductive mechanisms that pattern the neural plate and neural tube.

To determine the function of the candidate regulatory genes, we have generated mice that have loss of function and gain of function mutations. To study development the basal ganglia and the face, we are analyzing the phenotypes mice that lack function of several homeobox genes (Dlx-1, Dlx-2, Dlx-5 and Nkx-2.1). To study development of the cerebral cortex, we are analyzing the phenotype of mice that have mutations in other transcription factors (Tbr-1, Emx-1 and Gbx-2). These investigations have demonstrated the role of specific transcription factors in regulating neuronal specification, differentiation, migration and axon growth.  

In the long-term, we are interested in understanding the hierarchy of regulatory genes that orchestrate development of the forebrain and the face. To this end, we have begun to search for: (1) the proteins that regulate Dlx expression; (2) the targets of the DLX proteins; (3) proteins that interact with the DLX proteins which modulate their transcriptional activity. We would eventually like to integrate these findings to better understand human developmental disorders."
 

Mark Ryder, D.M.D.
 

"The principal area of research in my laboratory is on the effects of tobacco smoking on neutrophil and monocyte function.  These functional studies have employed flow cytometry, image analysis, enzymatic assays, ELISA, and microarrays to examine inflammatory and host response processes such as phagocytosis, oxidative burst, f-actin kinetics, chemotactic peptide binding kinetics, expression of selectins and integrins, cytokine release, and expression of m-RNAs.

Epidemiological evidence strongly suggests that tobacco use may be the most important preventable risk factor for periodontal diseases. Changes in the host response in general, and in neutrophil and monocyte function in particular may play a critical role in the pathogenesis of periodontal diseases in smokers.  The studies in my laboratory on the effects of  major components of tobacco smoke such as nicotine, cotinine, ammonia, benzene etc. have shed new light on the possible mechanisms of neutrophil and monocyte mediated destruction of periodontal tissues in smokers. Specifically, we have found that nicotine at low concentrations found in smoker's serum enhances the binding of chemotactic peptides.

In addition, in vitro whole smoke exposure appears to stimulate shedding of selectins and upregulation of integrins. These two phenomena may elevate the chemotaxis response resulting in an increased number of neutrophils in periodontal tissue. Once in the periodontal tissues, the neutrophils are exposed to higher levels of tobacco substances.  My laboratory has shown that these higher levels of nicotine and other substances alter the kinetics of two critical intermediate steps in neutrophil function: F-actin polymerization/depolymerization and the intracellular release of calcium. Specifically, these substances appear to "freeze" these functions at an elevated level. These findings may be related to other observations made in our laboratory on tobacco related neutrophil functions including a dose related elevation in the oxidative burst and release of secondary granule contents but a dose related suppression of phagocytosis and release of primary  granule contents.   Our observations have several important implications in tobacco related periodontal diseases.   Briefly, the increase in recruitment of neutrophils to periodontal tissues with an elevated oxidative burst and release of secondary granule contents can result in damage to healthy periodontal tissues.  On the other hand, the suppression of both phagocytosis and release of  primary granule contents (particularly myeloperoxidase- an important enzyme against the predominantly gram negative periodontopathic bacteria)  can significantly impair the host response.

In the past several years, we have turned our attention to the effects of acute smoke exposure on a second critical component of the inflammatory/host response, the monocyte.  We have observed that acute cigarette smoke alters the cytokine release profile of monocytes from a more reparative/ regenerative profile (e.g. the suppression of TGF-b release to a more destructive inflammatory profile (e.g. the elevation of IL-1b release). These effects of cigarette smoke on monocyte cytokines may also contribute to the increases in periodontal breakdown in smokers.    In the past year, through a collaborative arrangement with the Cancer Center at Mt. Zion Hospital, we have examined the effects of smoke on the expression of monocyte m-RNA¹s through microarray technology.  The results of these preliminary mocroarray studies confirm the findings from our previous work on monocytes.  In addition, microarray analysis has revealed several
previously unreported changes in m-RNA expression in moncytes exposed to smoke.

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Peter B. Sargent, Ph.D.
 

"Our laboratory is interested in the role that nicotinic receptors play in synaptic transmission.

Nicotinic receptors are membrane-bound ion channels that are gated by the transmitter acetylcholine (ACh) and also by exogenous ligands, such as nicotine  They underlie rapid synaptic transmission at all synapses in the peripheral nervous system.  Within the central nervous system, the diversity of nicotinic receptor (AChR) expression and the widespread effects of nicotinic agonists on behavior implies that these molecules are involved in a host of functions, including attention, learning and memory, and goal-directed behavior.  Some of the functions of AChRs have been attributed to their placement presynaptically and their ability to modulate transmitter release, while other effects are likely to be mediated postsynaptically.

To enhance our understanding of nicotinic synaptic mechanisms we have studied transmission at a particularly accessible cholinergic synapse in the peripheral nervous system: the giant calyceal synapse in the chick ciliary ganglion.  This synapse consists of a single, large calyx terminating on a dendrite-free postsynaptic neuron.  At late embryonic stages, the synapse is highly developed and allows the postsynaptic neurons to follow presynaptic action potentials at moderate to high frequencies.  The post-synaptic neuron is electrically compact, and whole-cell recordings can be made both from it and from the giant presynaptic terminal.  AChRs are found both postsynaptically, where they underlie rapid synaptic transmission, and presynaptically, where their function is not known. 

In the ciliary ganglion we have used imaging techniques and laser scanning confocal microscopy to examine the distribution of AChRs on the surface of ciliary neurons, and neurophysiological techniques to study the role that distinct classes of AChRs play in synaptic transmission.  We have shown that ACh activates at least two different AChRs: those containing a7 subunits (a7-AChRs) and those containing a3 subunits (a3-AChRs).  We have also shown that the distribution of these AChRs is distinct: a3-AChRs feature prominently at synaptic sites on the cell body, while a7-AChRs are found on collections of somatic spines, some distance away.  Current efforts are directed at understanding the basis of a3- and a7-AChR mediated synaptic currents.

In a related area, we have recently completed a study of presynaptic AChRs located at the calyceal synapse in the ciliary ganglion.  We have used calcium indicator dyes and real-time imaging to show that nerve released ACh acts back on the presynaptic terminal to elevate the calcium concentration.  We will next test the hypothesis that this feedback serves to enhance transmitter release during bouts of high frequency stimulation, when release might otherwise be depleted. 

We have recently started to examine nicotinic receptors and synaptic transmission in mammalian autonomic ganglia and intend eventually to move from the chick model to the mammalian one.  We have also extended our studies to nicotinic synaptic transmission in the central nervous system or rats.  In a study recently published in J. Neurophysiol., we examined transmission in spinal cord slices from a-motor neurons to glycinergic interneurons known as Renshaw cells.  Using immunofluorescence we showed that Renshaw cells express a4 and b2 AChR subunit immunoreactivities, and using whole-cell recording techniques we showed that that the receptors underlying motor neuron-Renshaw synaptic transmission have the pharmacological characteristics of a4b2-containing AChRs.  These AChRs have a high affinity for nicotine and may be altered during chronic exposure to nicotine, as occurs during smoking.  In a model for neonatal exposure to nicotine, we will be examining whether transmission onto Renshaw cells in rat pups is altered when their mothers are exposed chronically to nicotine." 

Richard A. Schneider, Ph.D.

"I am studying molecular and cellular mechanisms of normal and abnormal facial development. My current work focuses on the regulation of cell differentiation. Disruptions to this process result in a range of human birth defects. For example, premature cell differentiation within the osteogenic front of cranial sutures causes craniosynostoses. Conversely, a delay in differentiation of median edge epithelium leads to clefting of the secondary palate. Thus, the timing of differentiation among multiple populations of embryonic cells is a prerequisite for normal facial growth.

In my ongoing research, I am investigating how cranial populations of neural crest, ectoderm, and mesoderm learn when to differentiate into discrete facial structures such as cartilage, bone, epidermis, and muscle. I hypothesize that neural crest cells regulate their own temporal differentiation as well as that of adjacent mesoderm and ectoderm. To test this hypothesis, I am performing a series of neural crest transplants between two distinct avian species, quail and duck. My approach exploits the fact that quail and duck have considerably different rates of maturation, which provides a novel method for identifying time-dependant interactions between neural crest and adjacent populations. Results from my research can reveal etiologies of human craniofacial birth defects and potentially lead to new treatment and prevention strategies."

Caroline Shiboski, D.D.S., M.P.H., Ph.D.
 

"As an assistant clinical professor with expertise in epidemiology and oral medicine, I am currently involved in several research projects on the topic of oral health and immunodeficiency. In the area of HIV-related dental public health, I am conducting a follow-up study to a survey on utilization of dental care among HIV-positive women participating in the Women's Interagency HIV Study (WIHS), which began in 1994. In the area of HIV-related clinical epidemiology, and with colleagues from the Oral AIDS Center, I am involved with two projects: (1) As a co-investigator in the Reaching for Excellence in Adolescent Care and Health (REACH) Project, the main objective being to investigate, among HIV-positive adolescents, the occurrence of oral mucosal disease in relation to selected biological, behavioral, and socio-demographic variables. (2) As a co-investigator in the HIV Oral Transmission (HOT) study, which takes as its main objective to identify risk factors for oral acquisition of HIV infection. 

As an extension of my research activity in the area of oral disease in immunosuppressed populations, I am interested in oral disease among solid-organ transplant recipients. In 1998, in collaboration with colleagues from the Division of Periodontology (Dan Lauber) and from the School of Medicine (William Amend), I conducted a pilot study to investigate the natural history of oral mucosal disease and gingival enlargement in renal transplant recipients. I have presently applied for NIDCR funding to continue the study of this population. The objective of the proposed 5-year study among these patients is to investigate the long-term side effects of corticosteroids and new-generation immunosuppressants on the incidence of oral soft tissue disease and on changes in mandibular bone structure. A secondary goal is to determine whether change in the fractal dimension of mandibular bone predicts change in bone mineral density of various skeletal sites, and whether it may be used as a diagnostic tool to detect osteoporosis in this high-risk population of transplant recipients."

Michal Staninec, DDS, PhD

Clinical research on new dental materials and procedures; mechanical properties of dentin; bonding to laser-irradiated tooth surfaces

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Antoni P. Tomsia, Ph.D.  

Glass material seals; hydroxyapatite coatings on titanium alloy implants.

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Karin Vargervik, D.D.S.
 

"Our clinical research is focused on 1) characteristics of growth and development in cleft lip and palate, hemifacial microsomia and craniosynostosis syndromes, 2) delineation of factors contributing to abnormal development, 3) effects of the neuromuscular system on bone morphology and growth patterns under normal and perturbed conditions, 4) stability of craniofacial skeletal components after major reconstructive procedures, and 5) treatment outcomes following various types of management procedures in a team environment."

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Jane A. Weintraub, D.D.S., M.P.H.


Dr. Jane Weintraub is the Lee Hysan Professor of Oral Epidemiology and Dental Public Health and Director of the NIH-funded Center to Address Disparities in Children’s Oral Health (called the CAN DO Center).  Dr. Weintraub's research has focused on the epidemiology of oral conditions, the prevention of dental disease, and the evaluation of the effectiveness of dental programs and treatments. Most recently, she has been involved with clinical and community-based research to assess the efficacy or effectiveness of a variety of caries preventive methods including dental sealants, fluoride varnish, and combined caries management techniques.  The goal of the CAN DO Center is to prevent and reduce oral health disparities, with a focus on preventing early childhood caries.  Please see the CAN DO website for more details.  http://www.ucsf.edu/cando/
Dr. Weintraub, a board certified public health dentist, is currently the President-elect of the American Association of Public Health Dentistry.
 

Zena Werb, Ph.D.
 

"All cells in multicellular organisms are in contact with the extracellular matrix (ECM), which provides mechanical support, spatial cues and signals to regulate differentiation, proliferation and apoptosis. We are investigating the signal transduction mechanisms initiated by ECM, and how these pathways intersect with signals from growth and differentiation factors. We want to know how ECM, in cooperation with growth factors, mediates growth, differentiation, remodeling, cell migration, tissue invasion, and morphogenesis. As the cells change in response to ECM they also change their morphology and cytoskeletal organization. We are using two systems to elucidate these mechanisms.

Fibroblasts exist in either a quiescent state or in an activated migratory and tissue-remodeling state characteristic of wound healing. The composition of the ECM seen by the fibroblasts regulates these two states. The genes encoding ECM-degrading matrix metalloproteinases are upregulated in the activated fibroblasts by a signal transduction cascade initiated by integrins. We have begun to elucidate the kinase cascade activated by binding to integrins, resulting in activated transcription factors binding to promoter sequences in ECM-responsive genes. It is now clear that there are four distinct signaling pathways mediated by adhesion, that result in organization of focal adhesions, alteration in cell shape and migration, endocytosis and signaling for proteinases and their inhibitors. The molecular mechanisms involved in these distinct pathways are now being elucidated.
 

We want to understand how ECM diversity orchestrates changes in gene expression. It appears that several ECM receptors process extracellular information cooperatively, in collaboration with receptors for growth factors. We also need to elucidate what role the cytoskeleton plays in the processing of ECM information."
 
 
Joel White, DDS, MS

Clincal research on lasers and dental procedures 

Torsten Wittmann, PhD

My research program focuses on the function and spatiotemporal regulation of the microtubule cytoskeleton during the establishment and maintenance of cell polarity and other complex cell behaviors. Although actin polymerization dynamics and myosin-mediated contractility provide the force for cell shape changes, microtubules are fundamentally important for planar cell polarity and directed migration.

Microtubules are dynamic polymers that in cells frequently switch between polymerization and depolymerization. The idea that this non-equilibrium behavior allows microtubule ends to explore the cytoplasm to find and interact with specific targets is not new. However, this search-and-capture hypothesis has regained vigor by the discovery of a heterogenous group of proteins, referred to as +TIPs, that are functionally defined by their dynamic localization to growing microtubule ends in cells. The molecular functions of this microtubule plus end complex are not well understood. My laboratory uses classical biochemical techniques in combination with advanced live cell fluorescence light microscopy to examine the molecular mechanisms by which microtubules, +TIPs, and other cytoskeletal proteins determine cell behavior. Currently, our major experimental model system are planar polarized human keratinocytes that directionally migrate at the edge of an epithelial cell sheet. We will extend our studies into other tissue culture systems such as apical-basal polarized epithelial cells and endothelial cells that establish planar polarity in response to fluid shear stress.

 
http://www.ucsf.edu/~wittmann/

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