A potential role for B cells in suppressed immune responses in cord blood transplant recipients.

We evaluated immune reconstitution in 58 adults who received hematopoietic SCTs from allogeneic siblings (allosib), matched unrelated donors (MUD) or cord blood (CB) at 90-day intervals for 1 year post transplant. CB recipients had a higher incidence of infections in the first 100 days compared with allosib and MUD recipients. The number of circulating T cells was lower in CB recipients compared with MUD recipients at 90 days and compared with allosib recipients at 180 days. Spectratype analysis of the TCR Vß complementarity determining region 3 (CDR3) of patient lymphocytes revealed that the TCR repertoire remained poorly diversified even at 360 days in nearly all patients. In contrast, the number of circulating B cells was significantly elevated in CB recipients compared with allosib recipients throughout the first year post transplant and compared with MUD recipients at 9-12 months. Spectratype analysis of the B-cell receptor V(H) CDR3 showed that the B-cell repertoire was diversified in most patients by 90 days. CD5(pos) B cells from assayed CB recipients expressed intracellular IL-10 early post transplant. Our data suggest that B cells, in addition to T cells, may have a role in impaired immune responses in CB transplant patients.

Ex vivo expansion of umbilical cord blood stem cells for transplantation: growing knowledge from the hematopoietic niche.

Umbilical cord blood transplantation (UCBT) in adults is limited by the small number of primitive hematopoietic stem cells (HSC) in each graft, resulting in delayed engraftment post transplant, and both short- and long-term infectious complications. Initial efforts to expand UCB progenitors ex vivo have resulted in expansion of mature rather than immature HSC, confounded by the inability to accurately and reliably measure long-term reconstituting cells. Ex vivo expansion of UCB HSC has failed to improve engraftment because of resulting defects that promote apoptosis, disrupt marrow homing and initiate cell cycling. Here we discuss the future of ex vivo expansion, which we suggest will include the isolation of immature hematopoietic progenitors on the basis of function rather than surface phenotype and will employ both cytokines and stroma to maintain and expand the stem cell niche. We suggest that ex vivo expansion could be enhanced by manipulating newly discovered signaling pathways (Notch, Wnt, bone morphogenetic protein 4 and Tie2/angiopoietin-1) and intracellular mediators (phosphatase and tensin homolog and glycogen synthase kinase-3) in a manner that promotes HSC expansion with less differentiation. Improved methods for ex vivo expansion will make UCBT available to more patients, decrease engraftment times and allow more rapid immune reconstitution post transplant.

The evolution of the immunoglobulin heavy chain variable region (IgVH) in Leporids: an unusual case of transspecies polymorphism.

In domestic rabbit (Oryctolagus cuniculus), three serological types have been distinguished at the variable domain of the antibody H chain, the so-called V(H) a allotypes a1, a2, and a3. They correspond to highly divergent allelic lineages of the V(H) 1 gene, which is the gene rabbit utilizes in more than 80% of VDJ rearrangements. The sharing of serological V(H) a markers between rabbit and snowshoe hare (Lepus americanus) has suggested that the large genetic distances between rabbit V(H) 1 alleles (9-14% nucleotide differences) can be explained by unusually long lineage persistence times (transspecies polymorphism). Because this interpretation of the serological data is uncertain, we have determined the nucleotide sequences of V(H) genes expressed in specimens of Lepus species. Two sequence groups were distinguished, one of which occurred only in hare specimen displaying serological motifs of the rabbit V(H) a-a2 allotype. Sequences of this group are part of a monophyletic cluster containing the V(H) 1 sequences of the rabbit a2 allotype. The fact that this "transspecies a2 cluster" did not include genes of other rabbit V(H) a allotypes (a1, a3, and a4) is incompatible with the existence of a common V(H) a ancestor gene within the species, and suggests that the divergence of the V(H) a lineages preceded the Lepus vs Oryctolagus split. The sequence data are furthermore compatible with the hypothesis that the V(H)a polymorphism can be two times older than the divergence time between the Lepus and Oryctolagus lineages, which was estimated at 16-24 million years.

ATP-mediated changes in cross-subunit interactions in the RecA protein.

RecA protein undergoes ATP- and DNA-induced conformational changes that result in different helical parameters for free protein filaments versus RecA/ATP/DNA nucleoprotein filaments. Previous mutational studies of a particular region of the RecA oligomeric interface suggested that cross-subunit contacts made by residues K6 and R28 were more important for stabilization of free protein oligomers than nucleoprotein filaments [Eldin, S., et al. (2000) J. Mol. Biol. 299, 91-101]. Using mutant proteins with specifically engineered Cys substitutions, we show here that the efficiency of cross-subunit disulfide bond formation at certain positions in this region changes in the presence of ATP or ATP/DNA. Our results support the idea that specific cross-subunit interactions that occur within this region of the subunit interface are different in free RecA protein versus RecA/ATP/DNA nucleoprotein filaments.

Phe217 regulates the transfer of allosteric information across the subunit interface of the RecA protein filament.

BACKGROUND: ATP-mediated cooperative assembly of a RecA nucleoprotein filament activates the protein for catalysis of DNA strand exchange. RecA is a classic allosterically regulated enzyme in that ATP binding results in a dramatic increase in ssDNA binding affinity. This increase in ssDNA binding affinity results almost exclusively from an ATP-mediated increase in cooperative filament assembly rather than an increase in the inherent affinity of monomeric RecA for DNA. Therefore, certain residues at the subunit interface must play an important role in transmitting allosteric information across the filament structure of RecA. RESULTS: Using electron microscopic analysis of RecA polymer formation in the absence of DNA, we show that while wild-type RecA undergoes a slight decrease in filament length in the presence of ATP, a Phe217Tyr substitution results in a dramatic ATP-induced increase in cooperative filament assembly. Biosensor DNA binding measurements reveal that the Phe217Tyr mutation increases ATP-mediated cooperative interaction between RecA subunits by more than 250-fold. CONCLUSIONS: These studies represent the first identification of a subunit interface residue in RecA (Phe217) that plays a critical role in regulating the flow of ATP-mediated information throughout the protein filament structure. We propose a model by which conformational changes that occur upon ATP binding are propagated through the structure of a RecA monomer, resulting in the insertion of the Phe217 side chain into a pocket in the neighboring subunit. This event serves as a key step in intersubunit communication leading to ATP-mediated cooperative filament assembly and high affinity binding to ssDNA.

Human RAD52 exhibits two modes of self-association.

The human RAD52 protein plays an important role in the earliest stages of chromosomal double-strand break repair via the homologous recombination pathway. Individual subunits of RAD52 self-associate into rings that can then form higher order complexes. RAD52 binds to double-strand DNA ends, and recent studies suggest that the higher order self-association of the rings promotes DNA end-joining. Earlier studies defined the self-association domain of RAD52 to a unique region in the N-terminal half of the protein. Here we show that there are in fact two experimentally separable self-association domains in RAD52. The N-terminal self-association domain mediates the assembly of monomers into rings, and the previously unidentified domain in the C-terminal half of the protein mediates higher order self-association of the rings.

Group 1 CD1 genes in rabbit.

CD1 is an Ag-presenting molecule that can present lipids and glycolipids to T cells. The CD1 genes were first identified in the human, and since then, homologs have been identified in every mammalian species examined to date. Over a decade ago, CD1B and CD1D homologs were identified in the rabbit. We have extended this earlier study by identifying additional CD1 genes with the goal of developing the rabbit as an animal model to study the function of CD1 proteins. We constructed a thymocyte cDNA library and screened the library with CD1-specific probes. Based on nucleotide sequence analyses of the CD1(+) cDNA clones obtained from the library, we have identified two CD1A genes and one CD1E gene as well as determined the complete sequence of the previously identified CD1B gene. The CD1E(+) cDNA clones lacked the transmembrane and cytoplasmic domains and, if translated, would encode for a soluble or secreted CD1E protein. In addition, expression studies demonstrated that the CD1 genes were expressed in peripheral lymphoid tissues as well as in skin, gut, and lung. Of interest is the finding that CD1A2, CD1B, and CD1E genes were found to be expressed by rabbit B cell populations. The rabbit, with a complex CD1 locus composed of at least two CD1A genes, one CD1B gene, one CD1D gene, and one CD1E gene, is an excellent candidate as an animal model to study CD1 proteins.

A single 3' alpha hs1,2 enhancer in the rabbit IgH locus.

Multiple cis-acting elements including the intronic enhancer and the 3'alpha enhancer (3'alphaE) regulate expression of the Ig heavy chain genes during B cell development. A 3'alphaE is composed of DNase I-hypersensitive sites, hs1,2, hs3a,b, and hs4, found 3' of the murine Calpha gene as well as 3' of both human Calpha genes, Calpha1 and Calpha2. Rabbits have 13 Calpha genes, and we tested whether a 3'alphaE is associated with each of these genes. To identify 3'alphaE regions we developed a rabbit hs1,2 probe and used this to search for enhancer homologues of human hs1,2 in a genomic fosmid library. We identified a single hs1,2 fragment 8-kb downstream of Calpha13, the presumed 3'-most Calpha gene. We also identified and partially sequenced a new Calpha gene, Calpha14, located 6 kb upstream of Calpha13. Genomic Southern blot analysis confirmed that the rabbit genome contains only one hs1,2 enhancer region. We tested the enhancer activity of the hs1,2 with the SV40, V(H), and Ialpha promoters using the luciferase reporter gene in transient transfection assays and found that it significantly enhanced the activity of SV40 and V(H) promoters and slightly enhanced an Ialpha promoter. We conclude that the rabbit has a single hs1,2 enhancer that resides at the 3' end of the IgH gene cluster and may constitute one of the cis-elements regulating the expression of IgH genes.

Development of the antibody repertoire in rabbit: gut-associated lymphoid tissue, microbes, and selection.

Rabbits generate their antibody repertoire in three stages. First, a neonatal repertoire is generated by B lymphopoiesis in fetal liver and bone marrow and is limited by preferential V(H) gene segment usage. Between 4 and 8 weeks after birth a complex primary antibody repertoire is developed by somatically diversifying the neonatal repertoire through somatic hypermutation and a somatic gene conversion-like mechanism in gut-associated lymphoid tissue (GALT). In rabbits, unlike other species, the development of the primary antibody repertoire through somatic diversification of Ig genes appears to be dependent on intestinal microbial flora. The primary antibody repertoire is subsequently modified during antigen-dependent immune responses in which VDJ genes further diversify both by somatic hypermutation and by a gene conversion-like mechanism (the secondary repertoire). During the various stages of development, the antibody repertoire is modified and shaped by selective processes. In this review, we discuss the roles of GALT, microbes, and B-cell selection in generating antibody diversity in rabbits.

Intestinal microflora and diversification of the rabbit antibody repertoire.

The rabbit establishes its primary Ab repertoire by somatically diversifying an initial repertoire that is limited by restricted VH gene segment usage during VDJ gene rearrangement. Somatic diversification occurs in gut-associated lymphoid tissue (GALT), and by about 1-2 mo of age nearly all Ig VDJ genes are somatically diversified. In other species that are known to establish their primary Ab repertoire by somatic diversification, such as chicken, sheep, and cattle, diversification appears to be developmentally regulated: it begins before birth and occurs independent of exogenous factors. Because somatic diversification in rabbit occurs well after birth in GALT, the diversification process may not be developmentally regulated, but may require interaction with exogenous factors derived from the gut. To test this hypothesis, we examined Ab repertoire diversification in rabbits in which the appendix was ligated shortly after birth to prevent microbial colonization and all other organized GALT was surgically removed. We found that by 12 wk of age nearly 90% of the Ig VDJ genes in PBL were undiversified, indicating that intestinal microflora are required for somatically diversifying the Ab repertoire. We also examined repertoire diversification in sterilely derived remote colony rabbits that were hand raised away from contact with conventional rabbits and thereby acquired a different gut microflora. In these remote colony rabbits, GALT was underdeveloped, and 70% of the Ig VDJ genes in PBL were undiversified. We conclude that specific, currently unidentified intestinal microflora are required for Ab repertoire diversification.

Mutations in the N-terminal region of RecA that disrupt the stability of free protein oligomers but not RecA-DNA complexes.

We have introduced targeted mutations in two areas that make up part of the RecA subunit interface. In the RecA crystal structure, cross-subunit interactions are observed between the Lys6 and Asp139 side-chains, and between the Arg28 and Asn113 side-chains. Unexpectedly, we find that mutations at Lys6 and Arg28 impose sever defects on the oligomeric stability of free RecA protein, whereas mutations at Asn113 or Asp139 do not. However, Lys6 and Arg28 mutant proteins showed an apparent normal formation of RecA-DNA complexes. These results suggest that cross-subunit contacts in this region of the protein are different for free RecA protein filaments versus RecA-DNA nucleoprotein filaments. Mutant proteins with substitutions at either Lys6 or Arg28 show partial inhibition of DNA strand exchange activity, yet the mechanistic reasons for this inhibition appear to be distinct. Although Lys6 and Arg28 appear to be more important to the stability of free RecA protein, as opposed to the stability of the catalytically active nucleoprotein filament, our results support the idea that the cross-subunit interactions made by each residue play an important role in optimizing the catalytic organization of the active RecA oligomer.

Effects of tape and exercise on dynamic ankle inversion.

OBJECTIVE: To compare the effects of tape, with and without prewrap, on dynamic ankle inversion before and after exercise. DESIGN AND SETTING: Doubly multivariate analyses of variance were used to compare the taping and exercise conditions. Subjects were randomly assigned to a fixed treatment order as determined by a balanced latin square. The independent variables were tape application (no tape, tape with prewrap, tape to skin) and exercise (before and after). The dependent variables were average inversion velocity, total inversion, maximum inversion velocity, and time to maximum inversion. SUBJECTS: Thirty college-age male and female students (17 males, 13 females; mean age = 24.9 +/- 4.3 years, range, 19 to 39 years) were tested. Subjects were excluded from the study if they exhibited a painful gait or painful range of motion or had a past history of ankle surgery or an ankle sprain within the past 4 weeks. MEASUREMENTS: We collected data using electronic goniometers while subjects balanced on the right leg on an inversion platform tilted about the medial-lateral axis to produce 15 degrees of plantar flexion. Sudden ankle inversion was induced by pulling the inversion platform support, allowing the platform support base to rotate 37 degrees . Ten satisfactory trials were recorded on the inversion platform before and after a prescribed exercise bout. We calculated total inversion, time to maximum inversion, average inversion velocity, and maximum inversion velocity after sudden inversion. RESULTS: We found no significant differences between taping to the skin and taping over prewrap for any of the variables measured. There were significant differences between both taping conditions and no-tape postexercise for average inversion velocity, maximum inversion, maximum inversion velocity, and time to maximum inversion. The total inversion mean for no-tape postexercise was 38.8 degrees +/- 6.3 degrees , whereas the means for tape and skin and for tape and prewrap were 28.3 degrees +/- 4.6 degrees and 29.1 degrees +/- 4.7 degrees , respectively. After exercise, inversion increased by 1.0 degrees +/- 2.8 degrees for the no-tape condition, whereas the tape-to-skin and tape-over-prewrap inversion increased by 2.1 degrees +/- 3.2 degrees and 1.7 degrees +/- 2.2 degrees , respectively. CONCLUSIONS: There was no difference in the amount of inversion restriction when taping with prewrap was compared with taping to the skin. Tape and tape with prewrap significantly reduced the average inversion velocity, maximum inversion, maximum inversion velocity, and the time to maximum inversion. Both taping conditions offered residual restriction after exercise.

Heat distribution in the lower leg from pulsed short-wave diathermy and ultrasound treatments.

OBJECTIVE: To compare tissue temperature rise and decay after 20-minute diathermy and ultrasound treatments. DESIGN AND SETTING: We inserted 3 26-gauge thermistor microprobes into the medial aspect of the anesthetized triceps surae muscle at a depth of 3 cm and spaced 5 cm apart. Eight subjects received the diathermy treatment first, followed by the ultrasound treatment. This sequence was reversed for the remaining 8 subjects. The diathermy was applied at a frequency of 27.12 MHz at the following settings: 800 bursts per second, 400-microsecond burst duration, 850-microsecond interburst interval, peak root mean square amplitude of 150 W per burst, and an average root mean square output of 48 W per burst. The ultrasound was delivered at a frequency of 1 MHz and an intensity of 1.5 W/cm(2) in the continuous mode for 20 minutes over an area of 40 times the effective radiating area. The study was performed in a ventilated research laboratory. SUBJECTS: Sixteen (11 men, 5 women) healthy subjects (mean age = 23.56 +/- 4.73 years) volunteered to participate in this study. MEASUREMENTS: We recorded baseline, final, and decay temperatures for each of the 3 sites. RESULTS: The average temperature increases over baseline temperature after pulsed short-wave diathermy were 3.02 degrees C +/- 1.02 degrees C in site 1, 4.58 degrees C +/- 0.87 degrees C in site 2, and 3.28 degrees C +/- 1.64 degrees C in site 3. The average temperature increases over baseline temperature after ultrasound were only 0.17 degrees C +/- 0.40 degrees C, 0.09 degrees C +/- 0.56 degrees C, and -0.43 degrees C +/- 0.41 degrees C in sites 1, 2, and 3, respectively. The temperature dropped only 1 degrees C in 7.65 +/- 4.96 minutes after pulsed short-wave diathermy. CONCLUSIONS: We conclude that pulsed short-wave diathermy was more effective than 1-MHz ultrasound in heating a large muscle mass and resulted in the muscles' retaining heat longer.

The hRad51 and RecA proteins show significant differences in cooperative binding to single-stranded DNA.

The human Rad51 protein (hRad51), like its bacterial homologue RecA, catalyzes genetic recombination between homologous single and double-stranded DNA substrates. Using IAsys biosensor technology, we have examined the critical first step in this process, the binding of hRad51 and RecA to ssDNA. We show that hRad51 binds cooperatively and with high affinity to an oligonucleotide substrate in both the absence and presence of nucleotide cofactors. In fact, both ATP and ATPgammaS have a slight inhibitory effect on hRad51 binding affinity. We show that this results from a decrease in the intrinsic affinity of a given monomer for ssDNA, which is counterbalanced by an increase in the cooperative assembly of protein onto DNA. In contrast, we show that the dramatic NTP-induced increase in ssDNA binding affinity of RecA is accounted for by a significant increase in cooperative filament assembly and not by an increase in the intrinsic DNA binding affinity of monomeric RecA. These results demonstrate that although the hRad51 and RecA proteins display many structural and functional similarities, they show profound inherent mechanistic differences.

Intersubunit proximity of residues in the RecA protein as shown by engineered disulfide cross-links.

Mutational studies of regions that make up the oligomeric interface within the RecA protein filament structure have shown that F217 is an important determinant of RecA function and oligomer stability. All substitutions, other than Tyr and Cys, completely inhibit RecA activities and exhibit a substantial decrease in protein filament stability [Skiba, M. C., and Knight, K. L. (1994) J. Biol. Chem. 269, 3823-3828; Logan, K. M., et al. (1997) J. Mol. Biol. 266, 306-316]. Although the RecA crystal structure exhibits no obvious constraints that explain this mutational stringency, the structure does reveal a hydrophobic pocket in the neighboring monomer that may accommodate the F217 side chain. Together with the F217C mutation, we have introduced a series of Cys substitutions within the interacting surface on the neighboring monomer and have tested for disulfide formation under various conditions, e.g., with or without ATP and ssDNA. We show that the location of F217 in the crystal structure is in general agreement with its position in the catalytically active RecA-ATP-DNA complex. Functional studies with the mutant proteins support the idea that ATP-induced movement of the wild-type F217 side chain toward this hydrophobic pocket is important in mediating allosteric changes in the RecA protein structure.

B lymphocyte selection and age-related changes in VH gene usage in mutant Alicia rabbits.

Young Alicia rabbits use VHa-negative genes, VHx and VHy, in most VDJ genes, and their serum Ig is VHa negative. However, as Alicia rabbits age, VHa2 allotype Ig is produced at high levels. We investigated which VH gene segments are used in the VDJ genes of a2 Ig-secreting hybridomas and of a2 Ig+ B cells from adult Alicia rabbits. We found that 21 of the 25 VDJ genes used the a2-encoding genes, VH4 or VH7; the other four VDJ genes used four unknown VH gene segments. Because VH4 and VH7 are rarely found in VDJ genes of normal or young Alicia rabbits, we investigated the timing of rearrangement of these genes in Alicia rabbits. During fetal development, VH4 was used in 60-80% of nonproductively rearranged VDJ genes, and VHx and VHy together were used in 10-26%. These data indicate that during B lymphopoiesis VH4 is preferentially rearranged. However, the percentage of productive VHx- and VHy-utilizing VDJ genes increased from 38% at day 21 of gestation to 89% at birth (gestation day 31), whereas the percentage of VH4-utilizing VDJ genes remained at 15%. These data suggest that during fetal development, either VH4-utilizing B-lineage cells are selectively eliminated, or B cells with VHx- and VHy-utilizing VDJ genes are selectively expanded, or both. The accumulation of peripheral VH4-utilizing a2 B cells with age indicates that these B cells might be selectively expanded in the periphery. We discuss the possible selection mechanisms that regulate VH gene segment usage in rabbit B cells during lymphopoiesis and in the periphery.

Antigen-induced somatic diversification of rabbit IgH genes: gene conversion and point mutation.

During T cell-dependent immune responses in mouse and human, Ig genes diversify by somatic hypermutation within germinal centers. Rabbits, in addition to using somatic hypermutation to diversify their IgH genes, use a somatic gene conversion-like mechanism, which involves homologous recombination between upstream VH gene segments and the rearranged VDJ genes. Somatic gene conversion and somatic hypermutation occur in young rabbit gut-associated lymphoid tissue and are thought to diversify a primary Ab repertoire that is otherwise limited by preferential VH gene segment utilization. Because somatic gene conversion is rarely found within Ig genes during immune responses in mouse and human, we investigated whether gene conversion in rabbit also occurs during specific immune responses, in a location other than gut-associated lymphoid tissue. We analyzed clonally related VDJ genes from popliteal lymph node B cells responding to primary, secondary, and tertiary immunization with the hapten FITC coupled to a protein carrier. Clonally related VDJ gene sequences were derived from FITC-specific hybridomas, as well as from Ag-induced germinal centers of the popliteal lymph node. By analyzing the nature of mutations within these clonally related VDJ gene sequences, we found evidence not only of ongoing somatic hypermutation, but also of ongoing somatic gene conversion. Thus in rabbit, both somatic gene conversion and somatic hypermutation occur during the course of an immune response.

In vitro induction of the expression of multiple IgA isotype genes in rabbit B cells by TGF-beta and IL-2.

The rabbit genome has 13 different Calpha genes that are expressed at different levels in mucosal tissues. To analyze the factors involved in the differential expression of these Calpha genes, we cloned and sequenced the promoters of the Ialpha regions that control the expression of sterile mRNA. We found that all Calpha genes, including Calpha3 and Calpha8, which are not expressed, and Calpha4, which is expressed at high levels, have similar nucleotide sequences in the Ialpha region, and all contain the recognition elements for TGF-beta in the promoter. B lymphocytes from popliteal lymph nodes or Peyer's patch activated in vitro could be induced by TGF-beta to express sterile IgA transcripts of all IgA isotypes, except Calpha2, Calpha3, and Calpha8. Many single B lymphocytes transcribed sterile mRNA of more than one IgA isotype, which demonstrates that transcription of sterile mRNA alone does not regulate the IgA isotype switch. The addition of IL-2 led to the expression of transcripts of mature IgA of all isotypes, except Calpha2, Calpha3, and Calpha8. The predominantly expressed isotype in these experiments was Calpha4. With the use of an IgA4-specific mAb we found that IgA4+ plasma cells are unevenly distributed throughout the small intestine such that many of the IgA+ plasma cells in the duodenum-jejunum produced IgA4, whereas in the lower part of the ileum IgA4-producing cells were almost absent. Because the microbial flora varies throughout the intestine, we suggest that the microbial flora creates different local environments and thus affects either isotype switching or homing of IgA-expressing cells.

A role for RAD51 in the generation of immunoglobulin gene diversity in rabbits.

Ig VDJ genes in rabbit somatically diversify by both hyperpointmutation and gene conversion. To elucidate the mechanism of gene conversion of IgH genes, we cloned a rabbit homologue of RAD51, a gene involved in gene conversion in Saccharomyces cerevisiae (yeast), and tested whether it could complement a yeast rad51 mutant deficient in recombination repair. We found that rabbit RAD51 partially complemented the defect in switching mating types by gene conversion as well as in DNA double-strand break repair after gamma-irradiation. Further, by Western blot analysis, we found that levels of Rad51 were higher in appendix-derived B lymphocytes of 6-wk-old rabbits, a time at which IgH genes diversify by somatic gene conversion. We suggest that Rad51 is involved in somatic gene conversion of rabbit Ig genes.