Characterization of axolotl lampbrush chromosomes by fluorescence in situ hybridization and immunostaining.

The lampbrush chromosomes (LBCs) in oocytes of the Mexican axolotl (Ambystoma mexicanum) were identified some time ago by their relative lengths and predicted centromeres, but they have never been associated completely with the mitotic karyotype, linkage maps or genome assembly. We identified 9 of the axolotl LBCs using RNAseq to identify actively transcribed genes and 13 BAC (bacterial artificial clone) probes containing pieces of active genes. Using read coverage analysis to find candidate centromere sequences, we developed a centromere probe that localizes to all 14 centromeres. Measurements of relative LBC arm lengths and polymerase III localization patterns enabled us to identify all LBCs. This study presents a relatively simple and reliable way to identify each axolotl LBC cytologically and to anchor chromosome-length sequences (from the axolotl genome assembly) to the physical LBCs by immunostaining and fluorescence in situ hybridization. Our data will facilitate a more detailed transcription analysis of individual LBC loops.

Identification of immune and non-immune cells in regenerating axolotl limbs by single-cell sequencing.

Immune cells are known to be critical for successful limb regeneration in the axolotl (Ambystoma mexicanum), but many details regarding their identity, behavior, and function are yet to be resolved. We isolated peripheral leukocytes from the blood of adult axolotls and then created two samples for single-cell sequencing: 1) peripheral leukocytes (N = 7889) and 2) peripheral leukocytes with presumptive macrophages from the intraperitoneal cavity (N = 4998). Using k-means clustering, we identified 6 cell populations from each sample that presented gene expression patterns indicative of erythrocyte, thrombocyte, neutrophil, B-cell, T-cell, and myeloid cell populations. A seventh, presumptive macrophage cell population was identified uniquely from sample 2. We then isolated cells from amputated axolotl limbs at 1 and 6 days post-amputation (DPA) and performed single cell sequencing (N = 8272 and 9906 cells respectively) to identify immune and non-immune cell populations. Using k-means clustering, we identified 8 cell populations overall, with the majority of cells expressing erythrocyte-specific genes. Even though erythrocytes predominated, we used an unbiased approach to identify infiltrating neutrophil, macrophage, and lymphocyte populations at both time points. Additionally, populations expressing genes for epidermal cells, fibroblast-like cells, and endothelial cells were also identified. Consistent with results from previous experimental studies, neutrophils were more abundant at 1 DPA than 6 DPA, while macrophages and non-immune cells exhibited inverse abundance patterns. Of note, we identified a small population of fibroblast-like cells at 1 DPA that was represented by considerably more cells at 6 DPA. We hypothesize that these are early progenitor cells that give rise to the blastema. The enriched gene sets from our work will aid future single-cell investigations of immune cell diversity and function during axolotl limb regeneration.

Comparison of protein expression profile of limb regeneration between neotenic and metamorphic axolotl.

The axolotl (Ambystoma mexicanum) salamander, a urodele amphibian, has an exceptional regenerative capacity to fully restore an amputated limb throughout the life-long lasting neoteny. By contrast, when axolotls are experimentally induced to metamorphosis, attenuation of the limb's regenerative competence is noticeable. Here, we sought to discern the proteomic profiles of the early stages of blastema formation of neotenic and metamorphic axolotls after limb amputation by employing LC-MS/MS technology. We quantified a total of 714 proteins and qRT-PCR for selected genes was performed to validate the proteomics results and provide evidence for the putative link between immune system activity and regenerative potential. This study provides new insights for examination of common and distinct molecular mechanisms in regeneration-permissive neotenic and regeneration-deficient metamorphic stages at the proteome level.

Meningeal Foam Cells and Ependymal Cells in Axolotl Spinal Cord Regeneration.

A previously unreported population of foam cells (foamy macrophages) accumulates in the invasive fibrotic meninges during gap regeneration of transected adult Axolotl spinal cord (salamander Ambystoma mexicanum) and may act beneficially. Multinucleated giant cells (MNGCs) also occurred in the fibrotic meninges. Actin-label localization and transmission electron microscopy showed characteristic foam cell and MNGC podosome and ruffled border-containing sealing ring structures involved in substratum attachment, with characteristic intermediate filament accumulations surrounding nuclei. These cells co-localized with regenerating cord ependymal cell (ependymoglial) outgrowth. Phase contrast-bright droplets labeled with Oil Red O, DiI, and DyRect polar lipid live cell label showed accumulated foamy macrophages to be heavily lipid-laden, while reactive ependymoglia contained smaller lipid droplets. Both cell types contained both neutral and polar lipids in lipid droplets. Foamy macrophages and ependymoglia expressed the lipid scavenger receptor CD36 (fatty acid translocase) and the co-transporter toll-like receptor-4 (TLR4). Competitive inhibitor treatment using the modified fatty acid Sulfo-N-succinimidyl Oleate verified the role of the lipid scavenger receptor CD36 in lipid uptake studies in vitro. Fluoromyelin staining showed both cell types took up myelin fragments in situ during the regeneration process. Foam cells took up DiI-Ox-LDL and DiI-myelin fragments in vitro while ependymoglia took up only DiI-myelin in vitro. Both cell types expressed the cysteine proteinase cathepsin K, with foam cells sequestering cathepsin K within the sealing ring adjacent to the culture substratum. The two cell types act as sinks for Ox-LDL and myelin fragments within the lesion site, with foamy macrophages showing more Ox-LDL uptake activity. Cathepsin K activity and cellular localization suggested that foamy macrophages digest ECM within reactive meninges, while ependymal cells act from within the spinal cord tissue during outgrowth into the lesion site, acting in complementary fashion. Small MNGCs also expressed lipid transporters and showed cathepsin K activity. Comparison of 3H-glucosamine uptake in ependymal cells and foam cells showed that only ependymal cells produce glycosaminoglycan and proteoglycan-containing ECM, while the cathepsin studies showed both cell types remove ECM. Interaction of foam cells and ependymoglia in vitro supported the dispersion of ependymal outgrowth associated with tissue reconstruction in Axolotl spinal cord regeneration.

Role of the immune response in initiating central nervous system regeneration in vertebrates: learning from the fish.

The mammalian central nervous system is not able to regenerate neurons lost upon injury. In contrast, anamniote vertebrates show a remarkable regenerative capacity and are able to replace damaged cells and restore function. Recent studies have shown that in naturally regenerating vertebrates, such as zebrafish, inflammation is a key processes required for the initiation of regeneration. These findings are in contrast to many studies in mammals, where the central nervous system has long been viewed as an immune-privileged organ with inflammation considered one of the key negative factors causing lack of neuronal regeneration. In this review, we discuss similarities and differences between naturally regenerating vertebrates, and those with very limited to non-existing regenerative capacity. We will introduce neural stem and progenitor cells in different species and explain how they differ in their reaction to acute injury of the central nervous system. Next, we illustrate how different organisms respond to injuries by activation of their immune system. Important immune cell types will be discussed in relation to their effects on neural stem cell behavior. Finally, we will give an overview on key inflammatory mediators secreted upon injury that have been linked to activation of neural stem cells and regeneration. Overall, understanding how species with regenerative potential couple inflammation and successful regeneration will help to identify potential targets to stimulate proliferation of neural stem cells and subsequent neurogenesis in mammals and may provide targets for therapeutic intervention strategies for neurodegenerative diseases.

CXCL14-like immunoreactivity in growth hormone-containing cells of urodele pituitaries.

Immunohistochemical techniques were employed to investigate the distribution of a chemokine, namely, CXCL14-like immunoreactivity in the axolotl (Ambystoma mexicanum) and Japanese black salamander (Hynobius nigrescens) pituitaries. CXCL14-immunoreactive cells concentrated at an area of the pars distalis adjacent to the pars intermedia. We found that these cells correspond to the cells immunoreactive to an antibody against rat growth hormone (GH). Immunoelectron microscopy indicated that the CXCL14-like substance and GH coexisted on the secretory granules in the axolotl pituitary. Western blot analysis of axolotl pituitary extracts revealed the anti-human CXCL14 antibody labeled an approximately 16.6-kDa band that was not labeled by the anti-GH antibody. The CXCL14-like substance in the pars distalis may participate in GH functions in these species.

Molecular and biochemical characterization of the Mexican axolotl CD3 (CD3ε and CD3γ/δ).

In mammals, the T-cell receptor (TCR) complex expressed on mature T-cells consists of α/ß or γ/δ clonotypic heterodimers non-covalently associated with four invariant chains forming the CD3 complex (CD3γ, CD3δ, CD3ε and CD3ζ). The TCR is the unit implicated in the antigenic peptide recognition whereas the CD3 subunits present as three different dimers (δ-ε, γ-ε and ζ-ζ) in the receptor complex participate to the signal transduction and are indispensable for the expression of the TCR at the cell surface. We report the cloning, characterization and expression analysis of CD3γ/δ and CD3ε genes in an amphibian urodele, the Mexican axolotl. Amino acid comparisons show that important motifs and residues were preserved between the axolotl CD3 chains and various vertebrate CD3ε, CD3γ, CD3δ and CD3γ/δ chains. During ontogeny, CD3ε transcripts are first detected in the dorsal region of tail-bud embryos before thymus organogenesis. CD3γ/δ transcripts are first detected in the head of 4-week-old larvae. A cross-reactive polyclonal anti-CD3ε antibody was used for the co-immunoprecipitation of the two CD3 proteins of 25 and 29 kDa, respectively, associated with the 90-kDa αß TCR heterodimer.

Transcriptional response of Mexican axolotls to Ambystoma tigrinum virus (ATV) infection.

BACKGROUND: Very little is known about the immunological responses of amphibians to pathogens that are causing global population declines. We used a custom microarray gene chip to characterize gene expression responses of axolotls (Ambystoma mexicanum) to an emerging viral pathogen, Ambystoma tigrinum virus (ATV). RESULT: At 0, 24, 72, and 144 hours post-infection, spleen and lung samples were removed for estimation of host mRNA abundance and viral load. A total of 158 up-regulated and 105 down-regulated genes were identified across all time points using statistical and fold level criteria. The presumptive functions of these genes suggest a robust innate immune and antiviral gene expression response is initiated by A. mexicanum as early as 24 hours after ATV infection. At 24 hours, we observed transcript abundance changes for genes that are associated with phagocytosis and cytokine signaling, complement, and other general immune and defense responses. By 144 hours, we observed gene expression changes indicating host-mediated cell death, inflammation, and cytotoxicity. CONCLUSION: Although A. mexicanum appears to mount a robust innate immune response, we did not observe gene expression changes indicative of lymphocyte proliferation in the spleen, which is associated with clearance of Frog 3 iridovirus in adult Xenopus. We speculate that ATV may be especially lethal to A. mexicanum and related tiger salamanders because they lack proliferative lymphocyte responses that are needed to clear highly virulent iridoviruses. Genes identified from this study provide important new resources to investigate ATV disease pathology and host-pathogen dynamics in natural populations.

IgX antibodies in the urodele amphibian Ambystoma mexicanum.

Until recently, it was believed that urodele amphibians are able to synthesize only two immunoglobulin isotypes, IgM and IgY. We reinvestigated this issue in the Iberian ribbed newt Pleurodeles waltl and reported recently that this urodele expresses at least three isotypes: IgM, IgP and IgY. In this study, we demonstrate that another urodele, Ambystoma mexicanum, has also a third isotype whose amino acid sequence presents the highest homology with the amino acid sequence of Xenopus IgX. This isotype has typical Ig H-chain characteristics, could form multimers and is mainly expressed in mucosal tissues thereby indicating that it is likely the physiological counterpart of Xenopus IgX and mammalian IgA. Interestingly, no IgP could be found in A. mexicanum, in contrast to P. waltl, in which IgX was not found in previous investigations. These data indicate, for the first time, that different families of urodeles can express different immunoglobulin isotypes.

Structure, diversity and expression of the TCRdelta chains in the Mexican axolotl.

Mammals and birds have two major populations of T cells, based on the molecular composition and biological properties of their antigen receptors (TCR). alpha beta T cells recognize antigenic peptides linked to major histocompatibility complex (MHC) molecules, and gamma delta T cells recognize native peptide or non-peptide antigens independently of MHC. Very little is known about gamma delta T cells in ectothermic vertebrates. We have cloned and characterized the TCRdelta chains of an urodele amphibian, the Mexican axolotl (Ambystoma mexicanum). The Cdelta domain is structurally similar to its mammalian homologues and the transmembrane domain is very well conserved. Four of the six Valpha regions that can associate with Calpha (Valpha2, Valpha3, Valpha5 and Valpha6) can also associate with Cdelta, but no specific Vdelta regions were found. This suggests that the axolotl TRD locus is nested within the TRA locus, as in mammals, and that this organization has been present in all tetrapod vertebrates and in the common ancestor of Lissamphibians and mammals, for over 400 million years. Two Jdelta regions were identified, but no Ddelta segments were clearly recognized at the Vdelta-Jdelta junctions. This results in shorter and less variable CDR3 loops than in other vertebrates and the size range of the Vdelta-Jdelta junctions is similar to that of mammalian immunoglobulin light chains. Equivalent quantities of TRD mRNA were found in the lymphoid organs, and in the skin and the intestines of normal and thymectomized axolotls. The analysis of several Valpha/delta6-Cdelta and Vbeta7-Cbeta junctions showed that both the TCRdelta and the TCRbeta chains were limited in diversity in thymectomized axolotls.

Structure and diversity of Mexican axolotl lambda light chains.

We report here the structure of cDNA clones encoding axolotl light chains of the lambda type. A single IGLC gene and eight different potential IGLV genes belonging to four different families were detected. The axolotl Cgamma domain has several residues or stretches of residues that are typically conserved in mammalian, avian, and Xenopus Cgamma, but the KATLVCL stretch, which is well conserved in the Cgamma and T-cell receptor Cbeta domains of many vertebrate species, is not well conserved. All axolotl Vgamma sequences closely match several human and Xenopus Vgamma-like sequences and, although the axolotl Cgamma and Vgamma sequences are very like their tetrapod homologues, they are not closely related to nontetrapod L chains. Southern blot experiments suggested the presence of a single IGLC gene and of a limited number of IGLV genes, and analysis of IGLV-J junctions clearly indicated that at least three of the IGLJ segments can associate with IGLV1, IGLV2, or IGLV3 subgroup genes. The overall diversity of the axolotl Vgamma CDR3 junctions seems to be of the same order as that of mammalian Vgamma chains. However, a single IGLV4 segment was found among the 45 cDNAs analyzed. This suggests that the axolotl IGL locus may have a canonical tandem structure, like the mammalian IGK or IGH loci. Immunofluorescence, immunoblotting, and microsequencing experiments strongly suggested that most, if not all L chains are of the gamma type. This may explain in part the poor humoral response of the axolotl.

Structure, diversity, and repertoire of VH families in the Mexican axolotl.

The Mexican axolotl V(H) segments associated with the Igh C mu and C nu isotypes were isolated from anchored PCR libraries prepared from spleen cell cDNA. The eight new V(H) segments found bring the number of V(H) families in the axolotl to 11. Each V(H) had the canonical structural features of vertebrate V(H) segments, including residues important for the correct folding of the Ig domain. The distribution of ser AGC/T (AGY) and TCN codons in axolotl V(H) genes was biased toward AGY in complementarity-determining region-1 (CDR1) and TCN in framework region-1 (FR1); there were no ser residues in the FR2 region. Thus, the axolotl CDR1 region is enriched in DNA sequences forming potential hypermutation hot spots and is flanked by DNA sequences more resistant to point mutation. There was no significant bias toward AGY in CDR2. Southern blotting using family-specific V(H) probes showed restriction fragments from 1 (V(H)9) to 11-19 (V(H)2), and the total number of V(H) genes was 44 to 70, depending on the restriction endonuclease used. The V(H) segments were not randomly used by the H mu and H nu chains; V(H)1, V(H)6, and V(H)11 were underutilized; and the majority of the V(H) segments belonged to the V(H)7, V(H)8, and V(H)9 families. Most of the nine J(H) segments seemed to be randomly used, except J(H)6 and J(H)9, which were found only once in 79 clones.

Structure of MHC class I and class II cDNAs and possible immunodeficiency linked to class II expression in the Mexican axolotl.

Despite the fact that the axolotl (Ambystoma spp. a urodele amphibian) displays a large T-cell repertoire and a reasonable B-cell repertoire, its humoral immune response is slow (60 days), non-anamnestic, with a unique IgM class. The cytotoxic immune response is slow as well (21 days) with poor mixed lymphocyte reaction stimulation. Therefore, this amphibian can be considered as immunodeficient. The reason for this subdued immune response could be an altered antigenic presentation by major histocompatibility complex (MHC) molecules. This article summarizes our work on axolotl MHC genes. Class I genes have been characterized and the cDNA sequences show a good conservation of non-polymorphic peptide binding positions of the alpha chain as well as a high diversity of the variable amino acids positions, suggesting that axolotl class I molecules can present numerous antigenic epitopes. Moreover, class I genes are ubiquitously transcribed at the time of hatching. These class I genes also present an important polylocism and belong to the same linkage group as the class II B gene; they can be reasonably considered as classical class Ia genes. However, only one class II B gene has been characterized so far by Southern blot analysis. As in higher vertebrates, this gene is transcribed in lymphoid organs when they start to be functional. The sequence analysis shows that the peptide binding region of this class II beta chain is relatively well conserved, but most of all does not present any variability in the beta 1 domain in inbred as well as in wild axolotls, presuming a limited antigenic presentation of few antigenic epitopes. The immunodeficiency of the axolotl could then be explained by an altered class II presentation of antigenic peptides, putting into question the existence of cellular co-operation in this lower vertebrate. It will be interesting to analyze the situation in other urodele species and to determine whether our observations in axolotl represent a normal feature in urodele amphibians. But already two different models in amphibians, Xenopus and axolotl, must be considered in our search for understanding immune system and MHC evolution.

Abbreviated junctional sequences impoverish antibody diversity in urodele amphibians.

Of the six complementarity-determining regions (CDR) forming the structure of the Ab combining site, CDR3 of heavy chain is the most variable in length and sequence. Diversity of this loop is determined by the number of gene segments involved, extent of addition to or deletion from the joining genes, and imprecision of the site of recombination. In neonatal mice and Xenopus tadpoles, the last two factors occur less frequently than in adults, which in tadpoles result in low affinity Ab responses that do not mature. In contrast, adult urodele amphibians make larval-like responses and are notorious for lifelong poor immunocompetence. The mechanism for this is not known, and in this study we cloned germline VH genes from the axolotl and obtained rearrangements to these VH gene segments by reverse-transcriptase PCR. These sequences were analyzed for heavy chain junctional diversity and found to be even less variable than that in newborn mouse or Xenopus tadpoles, although for different reasons. Only 29% of the CDR3 loop in the axolotl consisted of somatically generated sequences, compared with 44% in tadpole, 39% in newborn mice, and 57% in both adult mice and Xenopus. This distinguishing feature of axolotl CDR3 results not only from shorter junctional sequences, but also unusually extensive integration of germline JH sequence. As the CDR3 loop is the most important portion of the Ig sequence for determining Ab combining site diversity, our data provide the molecular basis for a contributing factor in the deficient urodele amphibian Ab responses.

Isolation of Mhc class I cDNAs from the axolotl Ambystoma mexicanum.

Class I major histocompatibility complex (Mhc) cDNA clones were isolated from axolotl mRNA by polymerase chain reaction (PCR) and by screening a cDNA phage library. The nucleotide and predicted amino acid sequences show definite similarities to the Mhc class Ialpha molecules of higher vertebrates. Most of the amino acids in the peptide binding region that dock peptides at their N and C termini in mammals are conserved. Several amino acids considered to be important for the interaction of beta2-microglobulin with the Mhc alpha chain are also conserved in the axolotl sequence. The fact that axolotl class I A cDNAs are ubiquitously expressed and highly polymorphic in the alpha1 and alpha2 domains suggests the classical nature of axolotl class I A genes.

Activation by mitogens and superantigens of axolotl lymphocytes: functional characterization and ontogenic study.

Urodele amphibians have weak and slow immune responses compared to mammals and anuran amphibians. Using new culture conditions, we tested the ability of lymphocytes of a well-studied salamander, the Mexican axolotl (Ambystoma mexicanum) to proliferate in vitro with diverse mitogenic agents. We demonstrated that the axolotl has a population of B lymphocytes that proliferate specifically and with a high stimulation index to the lipopolysaccharide (LPS) known as a B-cell mitogen in mammals. This proliferative capacity is observed without significant changes throughout ontogenesis. In the presence of LPS, axolotl B lymphocytes are able to synthesize and secrete both isotopes of immunoglobulin described in this species, IgM and IgY. Moreover, a distinct lymphocyte subpopulation is able to poliferate significantly in response to the mitogens usually known as T-cell specific in mammals, phytohaemagglutinin (PHA) and concanavalin A (Con A). The activated cells are T lymphocytes, as shown by depletion experiments performed in vitro with monoclonal antibodies, and in vivo by thymectomy. Splenic T lymphocytes of young axolotls (before 10 months) do not have this functional ability, which suggests maturation and/or migration phenomena during T-cell ontogenesis in this species. Axolotl lymphocytes are able to proliferate in vitro with a significant stimulation index to staphylococcal enterotoxins A and B (SEA and SEB). These products act on mammalian lymphocytes as superantigens: in combination with products of the major histocompatibility complex (MHC), they bind T-cell receptors with particular V beta elements. The fact that these superantigens are able to activate lymphocytes of a primitive vertebrate suggests a striking conservation of molecular structures implied in superantigen presentation and recognition.

Effect of induced metamorphosis on the immune system of the axolotl, Ambystoma mexicanum.

Metamorphosis was induced in neotenic axolotls by immersion of the animals in a solution of thyroid hormone. Hematology of the axolotls was examined before, during, and after metamorphosis. There was a transient decrease in numbers of certain white blood cells during metamorphic climax and a permanent shift in the pattern of circulating cells. The eosinophilic granulocyte was the dominating leukocyte type in neotenes and in metamorphosing animals up to midclimax. Lymphocytes and neutrophilic granulocytes (polymorphs) significantly decreased during midclimax. In postmetamorphic axolotls, lymphocytes and polymorphs predominated. The observed decrease of some leukocytes in metamorphosing animals accords with a transient immunosuppression at metamorphic climax. Metamorphosed axolotls showed a humoral immune response (increase in circulating plasma cells) after repeated antigen challenge, whereas neotenic axolotls did not. Alterations in both cellular and humoral immunity are suggested to occur in both young and adult axolotls following experimental induction of metamorphosis.

Evolution of T cell receptor genes. Extensive diversity of V beta families in the Mexican axolotl.

We have cloned 36 different rearranged variable regions (V beta) genes encoding the beta-chain of the T cell receptor in an amphibian species, Ambystoma mexicanum (the Mexican axolotl). Eleven different V beta segments were identified, which can be classified into 9 families on the basis of a minimum of 75% nucleotide identity. All the cloned V beta segments have the canonical features of known mammalian and avian V beta, including conserved residues Cys23, Trp34, Arg69, Tyr90, and Cys92. There seems to be a greater genetic distance between the axolotl V beta families than between the different V beta families of any mammalian species examined to date: most of the axolotl V beta s have fewer than 35% identical nucleotides and the less related families (V beta 4 and V beta 8) have no more than 23.2% identity (13.5% at the amino acid level). Despite their great mutual divergence, several axolotl V beta are sequence-related to some mammalian V beta genes, like the human V beta 13 and V beta 20 segments and their murine V beta 8 and V beta 14 homologues. However, the axolotl V beta 8 and V beta 9 families are not significantly related to any other V beta sequence at the nucleotide level and show limited amino acid similarity to mammalian V alpha, V kappa III, or VH sequences. The detection of nine V beta families among 35 randomly cloned V beta segments suggests that the V beta gene repertoire in the axolotl is probably larger than presently estimated.

Mitogen-activated axolotl (Ambystoma mexicanum) splenocytes produce a cytokine that promotes growth of homologous lymphoblasts.

Culture supernatants (PHA-SNs) from axolotl splenocytes cultured with phytohemagglutinin-P (PHA) in medium supplemented with bovine serum albumin (BSA) were collected after 1, 2, and 3 days, pooled, treated to remove residual PHA, precipitated with saturated ammonium sulfate, dialyzed, aliquoted, and stored at -20 degrees C. PHA-SNs stimulated proliferation of homologous lymphoblasts, but not resting splenocytes. SDS-PAGE of metabolically labeled PHA-SNs revealed a band between 14 and 21 kDa. This corresponds to the M(r) of the gel fractions with biological stimulatory activity eluted from PHA-SNs. Blasts absorbed significant bioactivity of PHA-SNs whereas freshly harvested splenocytes did not. Although splenocytes cultured in medium supplemented with 1% fetal bovine serum (FBS) did not proliferate in response to PHA, they did secrete a cytokine with lymphoblast growth-promoting activity. Furthermore, PHA-induced lymphoblasts, initially cultured in medium supplemented with 0.25% BSA, could proliferate in response to PHA-SNs in 1% FBS-supplemented medium.