Salvatrice Ciccarese

Testicular cells lysostripped of H-Y antigen organize ovarian follicle-like aggregates

A suspension of free testicular cells were obtained by mild trypsin treatment from newborn BALB/c testes, and their plasma membrane H-Y antigen sites were blocked (lysostripped) by an excess of H-Y antibody of proven specificity and potency (45 min in ice). Upon 16 h of the Moscona-type rotation culture, these treated testicular cells yielded primarily spherical aggregates, more than half of which demonstrated a strong resemblance to ovarian follicles. The resemblance was particularly striking between the smallest testicular folliculoids and primordial ovarian follicles that abound in the newborn female gonad. Under the same condition, control serum-treated testicular cells primarily yielded cylindrical tubular structures that can be very long. Over a critical range, concentrations of H-Y antibody apparently influenced the frequency of testicular folliculoid formation. The above directly supports the proposed testis-organizing function of H-Y antigen and is certainly compatible with the genetic situation encountered in the wood lemming (Myopus schisticolor), that in the functional absence of H-Y antigen, XY gonadal cells readily organize an ovary.

Testis-Organizing H-Y Antigen and the Primary Sex-Determining Mechanism of Mammals

Publisher Summary This chapter discusses the sex-determining mechanism of mammals. The uniqueness of mammals lies in the clear partitioning of their sex-determining mechanism into two components: the primary or gonadal determination and the secondary or extragonadal sex determination. By this partitioning, the first component becomes independent and beyond the reach of sex steroids. The embryonic indifferent gonads of mammals have the inherent tendency to develop toward the ovary. The precise meaning of this general statement is likely to be the bisexual expression of the ovary-organizing plasma membrane component and its specific membrane-bound receptor. Testicular organogenesis that normally, but not always, depends upon the presence of the Y-chromosome is the responsibility of the two plasma membrane components; the male-specific but ubiquitously expressed H-Y antigen and its specific receptors expressed only by gonadal cells but of both sexes. Testis-organizing H-Y antigen is not an integral component of the plasma membrane. Instead, it utilizes β2 -microglobulin-MHC antigen dimers as its plasma membrane anchorage sites. This enables H-Y antigen to play a hormone like role during testicular organogenesis. Thus, the primary sex of mammals is determined not so much by the presence or the absence of the Y chromosome but rather by the expression or nonexpression of H-Y antigen.

Evolution of TRG clusters in cattle and sheep genomes as drawn from the structural analysis of the Ovine TRG2@ locus

The availability of genomic clones representative of the T-cell receptor constant gamma (TRGC) ovine genes enabled us to demonstrate, by fluorescent in situ hybridization (FISH) on cattle and sheep metaphases, the presence of two T-cell receptor gamma (TRG1@ and TRG2@) paralogous loci separated by at least five chromosomal bands on chromosome 4. Only TRG1@ is included within a region of homology with human TRG locus on chromosome 7, thus TRG2@ locus appears to be peculiar to ruminants. The structure of the entire TRG2@ locus, the first complete physical map of any ruminant animal TCR gamma locus, is reported here. The TRG2@ spans about 90 kb and consists of three clusters that we named TRG6, TRG2, and TRG4, according to the constant genes name. Phylogenetic analysis has highlighted the correlation between the grouping pattern of cattle and sheep variable gamma (TRGV) genes and the relevant TRGC; variable (V), joining (J), and constant (C) rearrange to be found together in mature transcripts. The simultaneous results on the TRG2@ locus molecular organization in sheep and on the phylogenetic analysis of cattle and sheep V expressed sequences indicate that at least six TRG clusters distributed in the two loci are present in these ruminant animals. The inferred evolution of TRG clusters in cattle and sheep genomes is consistent with a scenario where a minimal ancient cluster, containing the basic structural scheme of one V, one J, and one C gene, has undergone a process of duplication and intrachromosomal transposition.

Two plasma membrane antigens of testicular Sertoli cells and H-2-restricted versus unrestricted lysis by female T cells

Sertoli cell-only seminiferous tubules of sterile XX,Sxrl-male mice served as an excellent source of pure Sertoli cells. When H-2-compatible female mice were immunized 3 times with these Sertoli cells, resulting antibodies recognized two antigens on the plasma membrane of testicular Sertoli cells. They were male-specific, but ubiquitously expressed H-Y antigen and the cell lineage-specific antigen which Sertoli cells shared with ovarian follicular cells. Doubly primed (2 or 3 times in vivo, and once in vitro) cytotoxic T cells from these females lysed target Sertoli cells in both H-2-restricted and nonrestricted manners. While H-2-restricted killings were attributable to H-Y antigen, further work is needed to identify the Sertoli follicular cell lineage-specific antigen as the cause of H-2-nonrestricted killings.

H-Y Antigen in Testes of XX(BALB) XY (C3H) Chimaeric Male Mouse

Among experimentally produced BALB/C3H aggregation (Blastocyst fusion) chimaeras of the mouse, one fertile XX (BALB)/XY (C3H) male was identified who maintained 50% or more female cells in many parts of his body. Results of H-Y antibody absorption tests revealed an XY to XX transfer of testis-organizing H-Y antigen among testicular Sertoli and Leydig cells, but not among spleen and epidermal cells.

Artiodactyl emergence is accompanied by the birth of an extensive pool of diverse germline TRDV1 genes

Molecular cloning of cDNA from γ/δ T cells has shown that in sheep, the variable domain of the δ chain is chiefly determined by the expression of the TRDV1 subgroup, apparently composed of a large number of genes. There are three other TRDV subgroups, but these include only one gene each. To evaluate the extent and the complexity of the genomic TRDV repertoire, we screened a sheep liver genomic library from a single individual of the Altamurana breed and sheep fibroblast genomic DNA from a single individual of the Gentile di Puglia breed. We identified a total of 22 TRDV1 genes and the TRDV4 gene. A sequence comparison between germline and the rearranged genes indicates that, in sheep, the TRDV repertoire is generated by the VDJ rearrangement of at least 40 distinct TRDV1 genes. All germline TRDV1 genes present a high degree of similarity in their coding as well as in 5′ and 3′ flanking regions. However, a systematic analysis of the translation products reveals that these genes present a broadly different and specific repertoire in the complementarity-determining regions or recognition loops, allowing us to organize the TRDV genes into sets. We assume that selection processes operating at the level of ligand recognition have shaped the sheep TRDV germline repertoire. A phylogenetic study based on a sequence analysis of the TRDV genes from different mammalian species shows that the diversification level of these genes is higher in artiodactyl species compared to humans and mice.

Physical relationship between satellite I and II DNA in centromeric regions of sheep chromosomes

Fluorescence in situ hybridization (FISH) with probes representing sheep satellite I and satellite II DNAs shows a different distribution of the two repetitive DNA families in the centromeric region of most chromosomes. The single signal per chromosome produced by the satellite I probe suggests close proximity of this DNA family to the primary constriction. Satellite II produces two separate signals on the sister chromatids, and large blocks of satellite II DNA constitute most of the short arm of all acrocentric chromosomes. We have isolated and sequenced a phage clone containing a junction between discrete blocks of satellite I and satellite II sequences. The junction is characterized by an abrupt juxtaposition of arrays of the two satellites. The possibility that the peculiar structural features of this junction could have a functional significance is discussed.

Free H-Y antigen induces in vitro testicular differentiation of human XX embryonic indifferent gonads

In accordance with the anchorage site hypothesis, Daudi beta 2-microglobulin (-) HLA (-) human male Burkitt lymphoma cells are incapable of stably maintaining H-Y antigen on their plasma membrane; instead, they excrete it into the culture medium. The proposed testis-organizing function of Daudi H-Y antigen in solution, previously demonstrated in bovine ovarian embryonic cells, has been tested for the first time in human undifferentiated gonads. Cultured in the presence of Daudi excreted H-Y antigen, gonads obtained from early human embryos of 46, XX chromosomal constitution underwent precocious and complete testicular differentiation.

In vitro studies of gonadal organogenesis in the presence and absence of H-Y antigen

SummaryIn a very strict sense, the primary (gonadal) sex of mammals is determined not so much by the presence or absence of the Y but the expression or nonexpression of the evolutionary extremely conserved plasma membrane H-Y antigen. The central somatic blastema of embryonic indifferent gonads contains one cell lineage characterized by the possession of S−F differentiation antigen that differentiates into testicular Sertoli cells in the presence of H-Y and into ovarian follicular (granulosa) cells in its absence. This cell lineage appears to play the most critical role in gonadal differentiation. Whether or not testicular Leydig cells and ovarian theca cells are similarly derived from the common cell lineage has not been determined. Nevertheless, if given H-Y antigen, presumptive theca-cell precursors of the fetal ovary acquire hCG (LH?)-receptors—the characteristic of fetal Leydig cells.

Exon-intron organization of TRGC genes in sheep

A series of genomic clones derived from a sheep library were used to determine the germline configuration and the exon-intron organization of TRGC2, TRGC3, and TRGC4 genes. Based on the outcomes of molecular analysis, we compared and aligned the genomic sequences with the known complete cDNA sequences of sheep and deduced the exon-intron organization of TRGC genes in this ruminant animal, EX1, corresponding to the disulfide-linked constant domain, and EX3, corresponding to the transmembrane and cytoplasmatic domains, are similar in length in all genes. Conversely, the hinge-encoding EX2A, EX2B, and EX2C exons differ in number and length between genes, and EX2A contains the TTKPP motif irrespective of whether it occurs in single or triplicate form. The molecular data also indicate that at least one additional gene is present in sheep. Phylogenetic analysis grouped the ruminant TRGC genes in two clusters that could have emerged from two ancestral forms that underwent a series of duplications giving rise to the new sequences that were selected and then fixed in the ruminant lineages. A correlation between the cluster distribution in the phylogenetic tree of TRGC genes and their expression during fetal development is discussed.