Expression Programs Research Articles

Chromatin Boundaries, Insulators, and Long-Range Interactions in the Nucleus

Within the genome, expressed genes marked by "open" chromatin are often adjacent to silent, heterochromatic regions. There are also regions containing neighboring active genes with different programs of expression. In both cases, DNA sequence elements may function as insulators, either providing barriers that prevent the incursion of heterochromatic signals into open domains or acting to block inappropriate contact between the enhancer of one gene and the promoter of another. The mechanisms associated with insulation are diverse: Enhancer-blocking insulation is largely associated with the ability to stabilize the formation of loop domains within the nucleus. Barrier insulation is often associated with the ability to block propagation of silencing histone modifications. Here, we provide examples of both kinds of insulator action, derived initially from studies of the compound insulator element at the 5' end of the chicken β-globin locus. Such elements appear to have more general regulatory roles in the genome that have been exploited to provide insulator function where necessary to demarcate separate domains within the nucleus.

Infezioni impianto-correlate e biofilm batterico

Prosthetic joint infections are generally caused by a variety of Gram-positive and Gram-positive microrganisms. New species are continuously isolated, including anaerobes. The pathogenic mechanisms responsible for joint infections are well studied only for some bacteria, e.g. Staphylococcus aureus and Pseudomonas aeruginosa, while others are only partially understood. The most important virulence and microbiological factors involved in these infections are the bacterial adhesion on the native joint or prosthetic material and the biofilm production by bacteria involved in the infection. Biofilm formation results from a developmental programme of gene expression involving an intracellular signaling, or quorum-sensing. The biofilm consists of bacteria embedded within an extracellular polysaccharide matrix (EPS), where microrganims are protected from environmental influences including host immune responses and normal levels of conventional antimicrobial agents. Biofilm resistance is a multifactorial mechanism, which makes biofilm eradication difficult, and thus most biofilm-related infections often require prompt removal of the device. Some antibacterials are better than others in treating biofilm-associated bacteria.

Stimulating IFLA's Ethical Conscience: FAIFE 2003—2009

Reviews the activities of the Free Access to Information and Freedom of Expression (FAIFE) programme of IFLA from 2003 to 2009, based on three types of activity: intervention, education, and advocacy. FAIFE is still prepared to intervene in cases of threat to the stock, services and staff of libraries, but this was not the predominant form of activity during the period. With the aid of a grant from Swedish Sida, FAIFE has developed an education programme consisting of workshops using specially written sets of learning materials. These first dealt with the IFLA/UNESCO Internet Manifesto and Access to HIV/AIDS Information. Further sets of learning materials, on Libraries and Transparency, and Public Access to Health Information, have since been developed. The workshops, facilitated by FAIFE trainers, train local trainers to disseminate the message more widely in their own country and region. The centre of FAIFE's advocacy work has had the creation of the IFLA Manifesto on Transparency, Good Governance and Freedom from Corruption. A model of participative policy development, leading into training workshops, and a consequent strengthening of the advocacy capacity of the library profession can now be identified.

Insight into microRNA regulation by analyzing the characteristics of their targets in humans

BackgroundmicroRNAs (miRNAs) are believed to regulate their targets through posttranscriptional gene regulation and have the potential to silence gene expression via multiple mechanisms. Despite previous advances on miRNA regulation of gene expression, little has been investigated from a genome scale.ResultsTo gain new insight into miRNA regulation in humans, we used large scale data and carried out a series of studies to compare various features of miRNA target genes to that of non-miRNA target genes. We observed significant differences between miRNA and non-miRNA target genes for a number of characteristics, including higher and broader mRNA expression, faster mRNA decay rate, longer protein half-life, and longer gene structures. Based on these features and by analyzing their relationships we found that miRNA target genes, other than having miRNA repression, were most likely under more complex regulation than non-miRNA target genes, which was evidenced by their higher and broader gene expression but longer gene structures. Our results of higher and broader gene expression but fast mRNA decay rates also provide evidence that miRNA dampening of the output of preexisting transcripts facilitates a more rapid and robust transition to new expression programs. This could be achieved by enhancing mRNA degradation through an additive effect from multiple miRNA targeting.ConclusionGenome-scale analysis on the nature of miRNA target genes has revealed a general mechanism for miRNA regulation of human gene expression. The results of this study also indicate that miRNA target genes, other than having miRNA repression, are under more complex gene regulation than non-miRNA target genes. These findings provide novel insight into miRNA regulation of human gene expression.

Using a 3D virtual muscle model to link gene expression changes during myogenesis to protein spatial location in muscle

BackgroundMyogenesis is an ordered process whereby mononucleated muscle precursor cells (myoblasts) fuse into multinucleated myotubes that eventually differentiate into myofibres, involving substantial changes in gene expression and the organisation of structural components of the cells. To gain further insight into the orchestration of these structural changes we have overlaid the spatial organisation of the protein components of a muscle cell with their gene expression changes during differentiation using a new 3D visualisation tool: the Virtual Muscle 3D (VMus3D).ResultsSets of generic striated muscle costamere, Z-disk and filament proteins were constructed from the literature and protein-interaction databases. Expression profiles of the genes encoding these proteins were obtained from mouse C2C12 cells undergoing myogenesis in vitro, as well as a mouse tissue survey dataset. Visualisation of the expression data in VMus3D yielded novel observations with significant relationships between the spatial location and the temporal expression profiles of the structural protein products of these genes. A muscle specificity index was calculated based on muscle expression relative to the median expression in all tissues and, as expected, genes with the highest muscle specificity were also expressed most dynamically during differentiation. Interestingly, most genes encoding costamere as well as some Z-disk proteins appeared to be broadly expressed across most tissues and showed little change in expression during muscle differentiation, in line with the broader cellular role described for some of these proteins.ConclusionBy studying gene expression patterns from a structural perspective we have demonstrated that not all genes encoding proteins that are part of muscle specific structures are simply up-regulated during muscle cell differentiation. Indeed, a group of genes whose expression program appears to be minimally affected by the differentiation process, code for proteins participating in vital skeletal muscle structures. Expression alone is a poor metric of gene behaviour. Instead, the "connectivity model of muscle development" is proposed as a mechanism for muscle development: whereby the closer to the myofibril core of muscle cells, the greater the gene expression changes during muscle differentiation and the greater the muscle specificity.

Human microRNA in norm and pathology

MicroRNAs (miRNAs) are a class of RNA which controls gene expression at the posttranscription level. Binding with the target RNA, a miRNA can supress translation and/or induce degradation of mRNA. The studies of miRNAs have already shown that miRNA were essential to switch the programs of gene expression during embryo development as well as to control cell functioning of the adult organism. Alteration of the miRNA expression profile may appear not less important in development of pathology than better known structural variations of the proteins. The role of miRNA has been confirmed for a range of common diseases connected to impaired balance of cell proliferation, differentiation and programmed death. This review discusses specific features of miRNA-mediated regulation of gene expression and its role in normal and pathological development of muscle, immune, and nervous systems. The evidence of miRNA involvent in neurodegenerative disorders and mental disorders is demonstrated.

Histone acetylation and DNA demethylation of B cells result in a Hodgkin-like phenotype

A unique feature of the tumor cells (Hodgkin/Reed-Sternberg (HRS)) of classical Hodgkin lymphoma (cHL) is the loss of their B-cell phenotype despite their B-cell origin. Several lines of evidence suggest that epigenomic events, especially promoter DNA methylation, are involved in this silencing of many B-cell-associated genes. Here, we show that DNA demethylation alone or in conjunction with histone acetylation is not able to reconstitute the B-cell-gene expression program in cultured HRS cells. Instead, combined DNA demethylation and histone acetylation of B-cell lines induce an almost complete extinction of their B-cell-expression program and a tremendous upregulation of numerous Hodgkin-characteristic genes, including key players such as Id2 known to be involved in the suppression of the B-cell phenotype. Since the upregulation of Hodgkin-characteristic genes and the extinction of the B-cell-expression program occurred simultaneously, epigenetic changes may also be responsible for the malignant transformation of cHL. The epigenetic upregulation of Hodgkin-characteristic genes thus plays--in addition to promoter DNA hypermethylation of B-cell-associated genes--a pivotal role for the reprogramming of HRS cells and explains why DNA demethylation alone is unable to reconstitute the B-cell-expression program in HRS cells.

The Application of the Interpersonal Relationships and Self-Expression Program by Ronald B. Adler and its effectiveness

This study investigates the effect of the Interpersonal Relationships and Self-Expression Program by Ronald B. Adler in which the art therapy is applied, and the subject of this study was the females who want to improve their interpersonal relationship. Five interviewees who experienced personal counseling owing to difficulties in interpersonal relationships were selected as participants. The program has taken for seven weeks, from October 24th to December 5th, 2006, once a week for two hours each.<BR> To measure the effect, as a quantitative method, a questionnaire of self-expression problem area inserted in the Interpersonal Relationships and self expression Program by Adler was used before and after the program. As a qualitative analysis, the study employed self-portraits drawn by participants before and after the program as well as the written impression of participants after the program. As a result, all participants showed an increase in the self-expression score in five sub-areas of self-expression. Furthermore, the self-portrait showed the positive changes in participants self expression after the program, and the written impression also demonstrated that participants self-expression became positive as written 'I saw an improvement in self-confidence' or 'Now I can express myself in more active ways'. Therefore, it is clear that the interpersonal 'Relationships and Self-Expression Program' by Adler is effective in enhancing participants' self-expression ability.

Toward Understanding the Core Meiotic Transcriptome in Mammals and Its Implications for Somatic Cancer

Progression through meiotic development is in part controlled by an expression program that coordinates the timing of induction and time of function of numerous loci essential for the process. Whole-genome profiling of male germline expression in mouse, rat, and human provides important clues about the transcriptional regulatory machinery that drives the expression of its target genes. Among several thousand genes differentially expressed between testicular Sertoli and germ cells, a subset of conserved loci display highly similar meiotic and postmeiotic profiles across rodents and Homo sapiens. Mouse genes transcribed in the germline, but not in somatic control tissues, are frequently found to be important for sexual reproduction, thus correlating potentially specific expression and essential function in the male germline. In silico promoter analysis yields insight into DNA sequence conservation and the distribution of known regulatory elements within potential promoter regions of meiotic and postmeiotic genes. Some genes strongly expressed in male gonads are implicated in cancer, thus supporting the idea that gametogenesis and tumorigenesis may share molecular functions. Transcriptome, proteome, and protein network data reveal the kinetics of mRNA synthesis and translation in the germline, and help identify novel potentially important genes previously unassociated with the mammalian male germline.

Gene expression analysis illuminates the transcriptional programs underlying the functional activity of ex vivo-expanded granulocytes

Global gene expression analysis established the temporal expression patterns and programs underlying the development of functional activity of ex vivo-expanded (EXE) human granulocytes, as well as differences compared with peripheral blood (PB) granulocytes. CD34(+) progenitor cells were cultured for 3 wk to induce rapid expansion and granulocytic differentiation, with 40% CD15(+) cells by day 3 and 90% by day 12. Phagocytic and respiratory burst activity increased with the fraction of CD15(++)CD11b(+) cells (myelocytes to segmented) and peaked by day 17. However, only 25% of CD15(++)CD11b(+) cells were phagocytic, and respiratory burst activity was one-third that of PB granulocytes. EXE granulocytes from later days and PB granulocytes showed similar expression of Fc gamma receptors (-1A, -2A, -2C, -3A) and complement receptors (-1, -3, -4). Later downregulation of CD36 (expressed by macrophages) suggests lineage plasticity early in granulocytic differentiation. Expression in mature EXE and PB granulocytes was similar for most Fc gamma receptor-mediated phagocytosis signaling proteins, including high-level expression of Hck, Fgr, and the actin-related protein 2/3 complex. Lower expression of Lyn, Cdc42, pleckstrin, and PKC beta(I) by EXE granulocytes may explain decreased phagocytosis. PB and mature EXE granulocytes expressed similar levels of NADPH oxidase complex genes and receptors for fMLP-mediated respiratory burst. Lower burst activity by EXE granulocytes may result from lower expression of Raf1 and PKC zeta. Elevated expression of toll-like receptor (TLR)2, TLR1, and CD14 in mature EXE and PB granulocytes supports a role for the TLR2 and CD14 pathway in zymosan-mediated respiratory burst activity. Lower activity in EXE granulocytes may be due to greater expression of IRAK3, which inhibits TLR-mediated signaling.

Pathogenesis and associated diseases of Kaposi’s sarcoma-associated herpesvirus

Kaposi’s sarcoma-associated herpesvirus (KSHV) is the primary etiological agent of Kaposi’s sarcoma, primary effusion lymphoma and muticentric Castleman’s disease. In common with the other herpesviruses, KSHV exhibits both latent and lytic life cycles, both of which are characterized by distinct gene expression profiles and programs. KSHV encodes proteins which play essential roles in the inhibition of host adaptive and innate immunity, the inhibition of apoptosis, and the regulation of the cell cycle. KSHV also encodes several proteins which have transforming and intrcellular signalling activity.

Induction of melanocytes from embryonic stem cells and their therapeutic potential

Embryonic stem (ES) cells from many organisms have the capacity to generate in vitro a wide variety of cell types depending on their environment. Understanding precisely how such toti- or pluripotent cells may be driven towards a specific lineage represents a major challenge if our ambition of using ES cells to generate a ready supply of healthy cells for cell-based therapies for a range of diseases is to be realized. Recent advances have demonstrated that melanocytes and retinal pigmented epithelial (RPE) cells exhibiting the characteristics of their natural counterparts can be induced from undifferentiated ES cells grown on monolayers of specific stromal cell lines or by using a combination of Wnt3a, Endothelin-3 and SCF. The ability to induce pigment cells from ES cells promises to facilitate our understanding of the precise molecular mechanisms underlying this process and moreover enable us to distinguish the program of gene expression that underpins the choice made between generating a nerual crest-type melanocyte versus an RPE cell. Moreover, once the combination of signals required to induce a particular type of pigment cell are characterized, the way may be open for future cell-based therapy for various diseases caused by defective pigment cells.

Role of core promoter sequences in the mechanism of swarmer cell-specific silencing of gyrB transcription in Caulobacter crescentus

BackgroundEach Caulobacter crescentus cell division yields two distinct cell types: a flagellated swarmer cell and a non-motile stalked cell. The swarmer cell is further distinguished from the stalked cell by an inability to reinitiate DNA replication, by the physical properties of its nucleoid, and its discrete program of gene expression. Specifically, with regard to the latter feature, many of the genes involved in DNA replication are not transcribed in swarmer cells.ResultsWe show that for one of these genes involved in DNA replication, gyrB, its pattern of temporal expression depends upon an 80 base pair promoter region with strong resemblance to the Caulobacter crescentus σ73 consensus promoter sequence; regulation does not appear to be affected by the general strength of the promoter activity, as mutations that increased its conformity with the consensus did not affect its cell-cycle expression pattern. Transcription from the gyrB promoter in vitro required only the presence of the σ73 RNA polymerase (from E. coli) and the requisite nucleoside triphosphates, although a distinct binding activity, present in crude whole-cell extracts, formed a complex gyrB promoter DNA. We also assayed the effect on gyrB expression in strains containing mutations in either smc or dps, two genes encoding proteins that condense DNA. However we found there was no change in the temporal pattern of gyrB transcription in strains containing deletions in either of these genes.ConclusionThese experiments demonstrate that gyrB transcription does not require any auxiliary factors, suggesting that temporal regulation is not dependent upon an activator protein. Swarmer-specific silencing may not be attributable to the observed physical difference in the swarmer cell nucleoid, since mutations in either smc or dps, two genes encoding proteins that condense DNA, did not alter the temporal pattern of gyrB transcription in strains containing deletions in either of these genes. Rather a repressor that specifically recognizes sequences in the gyrB promoter region that are also probably essential for transcription, is likely to be responsible for controlling cell cycle expression.

Sex determination and sexual organ differentiation in flowering plants

The research in the genetics of sex determination and the differentiation of reproductive organs in flowering plants has long been a topic in recent years. Understanding the genetic and molecular mechanisms that control sex determination in flowering plants relies on detailed studies of the differentiation of sexual organs. Current theories about sex chromosomes have illuminated the mechanisms of plant sex determination. In addition, recent progress in cloning floral homeotic genes which regulate the identity of the floral organs has generated molecular markers to compare the developmental programs of male, female and hermaphrodite flowers in several species. In this review, the authors focus attention on these recent findings and provide a brief overview of the genetics of plant sex determination and the mechanism of sex determination gene expression and gene programs.

Similarities and differences in genome-wide expression data of six organisms.

Comparing genomic properties of different organisms is of fundamental importance in the study of biological and evolutionary principles. Although differences among organisms are often attributed to differential gene expression, genome-wide comparative analysis thus far has been based primarily on genomic sequence information. We present a comparative study of large datasets of expression profiles from six evolutionarily distant organisms: S. cerevisiae, C. elegans, E. coli, A. thaliana, D. melanogaster, and H. sapiens. We use genomic sequence information to connect these data and compare global and modular properties of the transcription programs. Linking genes whose expression profiles are similar, we find that for all organisms the connectivity distribution follows a power-law, highly connected genes tend to be essential and conserved, and the expression program is highly modular. We reveal the modular structure by decomposing each set of expression data into coexpressed modules. Functionally related sets of genes are frequently coexpressed in multiple organisms. Yet their relative importance to the transcription program and their regulatory relationships vary among organisms. Our results demonstrate the potential of combining sequence and expression data for improving functional gene annotation and expanding our understanding of how gene expression and diversity evolved.

Chromatin as a tool for the study of genome function in cancer.

The transition to malignancy requires an extensive reconfiguration of the genome's expression program that does not result entirely from actual changes in primary DNA sequence-i.e., mutation. Epigenetic-meta-DNA-gene expression states result from an assembly over a given locus of a poorly understood nucleoprotein entity that includes histones and other architectural components of chromatin, nonhistone DNA-bound regulators, and additional chromatin-bound polypeptides. This structure is rapidly reestablished in the wake of the DNA replication fork, thus ensuring its persistence in rapidly proliferating cells and thereby yielding an exceptionally stable mode of gene expression. Chromatin is the perfect vehicle for enabling such genome control. During S phase both covalently modified histones and histone-associated regulatory proteins distribute to the newly synthesized daughter chromatids in a form of "molecular dowry" inherited from the G(1) state of the genome, and impose a specific mode of function on the underlying DNA. An extensively studied example of chromatin-based epigenetic inheritance connects DNA methylation to the targeting of chromatin remodeling and modification. In a broad sense, however, genome reprogramming in cancer is associated with the remodeling of a multitude of regulatory DNA stretches-e.g., promoters, enhancers, locus control regions (LCRs), insulators, etc.-into a specific chromatin architecture. This architectural entity provides a general molecular signature of the cancer epigenome that complements and significantly expands its DNA methylation-based component.

Roles of the stress-induced gene IEX-1 in regulation of cell death and oncogenesis.

In response to changes in the external environment cells must initiate a coordinated program of gene expression for them to adapt. IEX-1 (immediate early response gene X-1) is precisely regulated by multiple transcription factors among which p53, NF-kappaB/rel, Sp1 and c-Myc play central roles, to ensure rapid and transient expression of IEX-1 in cells under a variety of stress conditions. Overexpression of IEX-1 renders some cells sensitive to apoptosis and accelerates cell cycle progression, but reduces proliferation of other cells, whereas disruption of IEX-1 expression is associated with decreases in both apoptosis and cell cycle progression. In sharp contrast to in vitro studies, in vivo constitutive expression of IEX-1 prevents activated T cells but not B cells from apoptosis, as shown using IEX-1-transgenic mice that target IEX-1 expression specifically to lymphocytes driven by the Emu enhancer. The animals developed a lupus-like disease and subsequently a high incidence of T cell lymphomas when they aged, due to insufficient apoptosis of T cells. These varied effects of IEX-1 on cell death and cell cycle progression in a cell-context dependent fashion implicate that IEX-1 is involved in more than one signaling pathway, understanding of which will certainly improve our knowledge with respect to cancer biology, cell death and cell cycle regulation.

Meeting summary: Signal transduction pathways in immune and inflammatory cells. November 30-December 3, 2000, Amelia Island, Florida, U.S.A.

Throughout this symposium, recurrent themes were highlighted that may provide important clues to the pathogenesis of mucosal inflammation and IBD. First, the mucosal immune system is unique: Studies describing signaling paradigms in peripheral immunocytes should be re-explored in the gut where the rules that govern cell signaling may not be the same. Paradigms are a point of departure to characterize similarities and differences in mucosal immunity. A good example is a differential requirement for costimulation through CD2 in lamina propria T cells compared with peripheral T cells. Furthermore, a new definition of T-cell "costimulation" is beginning to emerge. Costimulatory molecules may function to overcome physical barriers by allowing cognate interactions between other molecules or by targeting signaling complexes to membrane microdomains. This concept also relates to another recurrent theme: Interactions between signaling pathways and the cytoskeleton are functionally important. Finally, we were introduced to the novel concept of metabolic parameters as a readout for signal transduction in the immune system. In the recent past, cell signaling has been viewed as a linear exercise, connecting a cell surface receptor to a series of intermediate molecules to a program of gene expression. However, signal transduction is in fact a three-dimensional exercise in cell biology. The future challenge, as pointed out in the keynote address, is to integrate reductionist models into reality and describe networks of signal transduction pathways in complex biosystems. "Threshold" responses were emphasized, with a small incremental increase or decrease in enzymatic activity leading to an on-off phenomenon referred to as a "molecular switch." In IBD, minute genetically determined differences in enzymatic activity may be critical. This point emphasizes the power of a genetic approach in IBD. Without strong genetic evidence, it is unlikely that fuctional assays will clarify the importance of small differences in enzymatic activity that may have dramatic biologic consequences. This symposium identified recently described signal transduction molecules that may be attractive therapeutic targets in IBD. Characterization of signaling molecules such as SLP-76, SLAM, SAP, and Fyb in the mucosal immune system will be an important area of future research. Ultimately, well-developed scientific hypotheses need to be tested in human beings. This paradigm was perhaps best illustrated by PPARgamma, where reductionist models and mouse experiments have recently lead to small trials suggesting proof of concept in human IBD. This meeting also emphasized a renewed interest in innate immunity in IBD and inflammation research. The role of enteric flora in initiating and perpetuating inflammation in animal models of IBD suggests at some level the importance of the innate immune response. The role of TLRs and bacterial interactions were discussed, as was NF-kappaB as the prominent transcription factor target of innate immune activation. Numerous bridges between innate and adaptive immunity were highlighted, including IL-10, IL-12, IL-18, and IFN-gamma. Their production during an innate immune response can profoundly affect functional T-cell responses in humans. In conclusion, the challenge of understanding signal transduction in IBD is one of integrating well-characterized inflammatory pathways into a complex biologic system that is inhabited by diverse cell types that communicate, and is characterized by interactions with a complex microbial environment. Making sense of this complexity is a daunting task that will require a multifactorial approach utilizing reductionist systems, mouse models, genetic studies, and ultimately human clinical trials.

The role of CREB and other transcription factors in the pharmacotherapy and etiology of depression

Psychiatric diseases are genetically complex and consequently, altered programs of gene expression have been hypothesized as the molecular basis of psychopathology. Since transcription factors represent the final communicative link between receptor activation and the orchestration of programs of gene expression, they are prime targets for studies on both the pharmacotherapy and the etiology of depression. The cyclic AMP response element binding protein (CREB) and the glucocorticoid receptor (GR) are altered by chronic treatment with antidepressants. Since it is phosphorylated CREB (pCREB) that determines its transcriptional activity, it is pertinent that some antidepressants have been shown to reduce pCREB in brain in vivo and in tissue culture in vitro. Moreover, pCREB is downregulated in human fibroblasts from patients with major depression and in postmortem brain of suicide victims with a history of depression. With regard to GR, its mRNA, immunoreactivity, density and cytoplasmic-nuclear translocation are increased by antidepressants. While transcription factor mediated programs of gene expression relevant to either the pharmacotherapy or the etiology of depression are still largely elusive, studies utilizing modern technologies such as differential display and cDNA microarrays promise to lead eventually to the identification of structure and function of psychophathologically relevant target genes.

Characterization of five novel dehydration-responsive homeodomain leucine zipper genes from the resurrection plant Craterostigma plantagineum.

Homeodomain leucine zipper (HDZip) genes encode putative transcription factors that are unique to plants. A function in regulating processes that are specific for plants is postulated, such as responses to environmental cues and developmental signals. This is supported by a growing body of evidence resulting from studies of HDZip genes in a variety of species. In addition to the previously isolated CPHB-1 and -2 genes, this paper reports the isolation of members of five families of Craterostigma plantagineum homeobox leucine zipper genes (CPHB) via a yeast one-hybrid screening approach. Based on the sequence homology and protein interactions the encoded proteins (CPHB-3/4/5/6/7) were classified into HDZip class II and I genes. Homo- and heterodimerization of CPHB proteins within the same structurally related class has been demonstrated and the DNA-binding activity of CPHB proteins to two homeodomain recognition elements (HDE1 and HDE2) has been compared in yeast. All families of CPHB genes were modulated in their expression in response to dehydration in leaves and roots. CPHB-6 and CPHB-7 transcripts accumulated in leaves during early stages of dehydration and decreased after prolonged dehydration. Both transcripts were also induced in ABA-treated callus. CPHB-3/4/5 were down-regulated by dehydration in both leaves and roots. The results support the role of HDZips in regulating programs of gene expression in C. plantagineum that lead to desiccation tolerance.