Figure 3. Eden_express mice exhibit decreased frequencies of peripheral CD8+ T cells. Flow cytometric analysis of peripheral blood was utilized to determine T cell frequency. Normalized data are shown. Abbreviations: WT, wild-type; REF, homozygous reference mice; HET, heterozygous variant mice; VAR, homozygous variant mice. Mean (μ) and standard deviation (σ) are indicated.

Figure 4. Eden_express mice exhibit decreased frequencies of peripheral naive CD8 T cells in CD8 T cells. Flow cytometric analysis of peripheral blood was utilized to determine T cell frequency. Normalized data are shown. Abbreviations: WT, wild-type; REF, homozygous reference mice; HET, heterozygous variant mice; VAR, homozygous variant mice. Mean (μ) and standard deviation (σ) are indicated.

Figure 5. Eden_express mice exhibit increased frequencies of peripheral central memory CD8 T cells in CD8 T cells. Flow cytometric analysis of peripheral blood was utilized to determine T cell frequency. Normalized data are shown. Abbreviations: WT, wild-type; REF, homozygous reference mice; HET, heterozygous variant mice; VAR, homozygous variant mice. Mean (μ) and standard deviation (σ) are indicated.

Figure 6. Eden_express mice exhibit increased expression of CD44 on peripheral T cells. Flow cytometric analysis of peripheral blood was utilized to determine CD44 MFI. Normalized data are shown. Abbreviations: WT, wild-type; REF, homozygous reference mice; HET, heterozygous variant mice; VAR, homozygous variant mice. Mean (μ) and standard deviation (σ) are indicated.

Figure 7. Eden_express mice exhibit increased expression of CD44 on peripheral CD8+ T cells. Flow cytometric analysis of peripheral blood was utilized to determine CD44 MFI. Normalized data are shown. Abbreviations: WT, wild-type; REF, homozygous reference mice; HET, heterozygous variant mice; VAR, homozygous variant mice. Mean (μ) and standard deviation (σ) are indicated.

The Eden_express phenotype was identified among N-ethyl-N-nitrosourea (ENU)-mutagenized G3 mice of the pedigree R5219, some of which exhibited an increase in the B to T cell ratio (Figure 1) as well as reduced frequencies of T cells (Figure 2), CD8+ T cells (Figure 3), and naïve CD8 T cells in CD8 T cells (Figure 4) with concomitant increased frequencies of central memory CD8 T cells in CD8 T cells (Figure 5), all in the peripheral blood. The expression of CD44+ on peripheral blood T cells (Figure 6) and CD8+ T cells (Figure 7) was increased.

Figure 8. Linkage mapping of the increased central memory CD8 T cells in CD8 T cells frequency phenotype using a recessive model of inheritance. Manhattan plot shows -log10 P values (Y-axis) plotted against the chromosome positions of 67 mutations (X-axis) identified in the G1 male of pedigree R5219. Normalized phenotype data are shown for single locus linkage analysis without consideration of G2 dam identity. Horizontal pink and red lines represent thresholds of P = 0.05, and the threshold for P = 0.05 after applying Bonferroni correction, respectively.

Whole exome HiSeq sequencing of the G1 grandsire identified 67 mutations. All of the above anomalies were linked by continuous variable mapping to a mutation in Ppp3cb: a C to A transversion at base pair 20,528,195 (v38) on chromosome 14, or base pair 18,379 in the GenBank genomic region NC_000080 encoding Ppp3cb. The strongest association was found with a recessive model of inheritance to the normalized frequency of central memory CD8 T cells in CD8 T cells, wherein one variant homozygote departed phenotypically from 17 heterozygotes and 12 homozygous reference mice with a P value of 7.13 x 10^-11 (Figure 8). A substantial semidominant effect was observed in most of the assays.

The mutation corresponds to residue 619 in the mRNA sequence NM_008914 within exon 4 of 14 total exons.

The mutated nucleotide is indicated in red. The mutation results in substitution of cysteine 162 for a premature stop codon (C162*) in the encoded protein.

Ppp3cb encodes calcineurin Aβ (CnAβ), a calcineurin catalytic subunit isoform. All of the CnA proteins have a catalytic domain that is highly homologous to other serine/threonine protein phosphatases (amino acids 2-310 in CnAβ) (Figure 9). Within the catalytic domain is a poly-proline motif (amino acids 11-20 in CnAβ) that is specific for the CnAβ catalytic subunit (1). The CnA proteins have three C-terminal regulatory domains that include a CnB binding domain (amino acids 256-262 and 305-310 in CnAβ), a CaM-binding domain (amino acids 401-423 in CnAβ), and an autoinhibitory domain (amino acids 474-496 in CnAβ) (1;2). Ppp3cb can be alternatively spliced upon insulin-like growth factor 1 induction to generate a CnAβ1 isoform (3). The CnAβ1 isoform does not have an autoinhibitory domain, and contains a unique C-terminal domain to CnAβ (4). The Eden_express mutation results in substitution of cysteine 162 for a premature stop codon (C162*). Amino acid 162 is within the catalytic domain.

Please see the record Copacabana for more information about Ppp3cb.

Calcineurin (alternatively, PP2B) is a calcium- and calmodulin (CaM)-dependent serine/threonine protein phosphatase that consists of a catalytic subunit and a regulatory calcium-binding subunit, termed calcineurin A (CnA) and calcineurin B (CnB), respectively. Calcineurin has functions in T cell activation, activation-induced cell death (AICD), T cell tolerance, ion channel regulation, cardiac myocyte hypertrophy, sperm motility, synaptic endocytosis, and Alzheimer’s disease (5-8). Upon calcineurin activation, it dephosphorylates members of the nuclear factor of activated T cells (NFAT) family, promoting their translocation from the cytosol to the nucleus and subsequent induction of the transcription of NFAT target genes such as IL-2 growth factor, IFN-γ, and IL-4.  In addition to cytokine production, calcineurin-NFAT signaling mediates T cell maturation, synaptic transmission in neurons, vascular patterning in embryonic development, hypertrophic growth of the heart, and regulation of oxidative/slow fiber content in glycolytic/fast muscles (i.e., gastrocnemius, tibialis anterior, biceps, and triceps) (9;10).

CnAβ is required for the spontaneous survival of naïve T cells (11). Naïve T cells from Ppp3cb-deficient (Ppp3cb^-/-) mice exhibited increased spontaneous apoptosis that could be blocked by IL-7 and IL-15. Ppp3cb^-/- mice exhibit a reduction in CD3⁺ T cells in the peripheral blood compared to that in wild-type mice (12). In addition, the frequency of both thymic and splenic CD4⁺ and CD8⁺ cells in the Ppp3cb^-/- mice was reduced compared to that in wild-type mice. The numbers of single positive T cells increased in the Ppp3cb^-/- mice with age to levels comparable to wild-type mice (8). Thymus cellularity was also reduced in the Ppp3cb^-/- mice. Splenic T cells from Ppp3cb^-/- mice exhibited reduced proliferation induced by CD3 cross-linking or PMA/ionomycin. CnAα is able to partially compensate for the function of CnAβ in T cell activation, but both are required for efficient cell activation. After calcineurin-induced activation, NF-AT forms a complex with FOXP3 to induce regulatory T cell (T_reg) cell generation through the induction of Il2ra (CD25) and Ctla4 (CD152) (13). Loss of CnAβ expression results in deficient T_reg cell generation with a concomitant expansion of mature T cells with an activated phenotype (8). Calcineurin has a several functions including a role in apoptosis of T and B cells (14-16) and neuronal cells (17). In lymphocytes, calcineurin and NF-AT function in apoptosis by mediating the induction of Fas and FasL, which transduce an apoptotic signal upon T cell activation (18;19).

The phenotypes observed in the Eden_express mice indicates that CnAβ^Eden_express exhibits loss of function.

PCR program

1) 94°C 2:00
2) 94°C 0:30
3) 55°C 0:30
4) 72°C 1:00
5) repeat steps (2-4) 40x
6) 72°C 10:00
7) 4°C hold

The following sequence of 523 nucleotides is amplified (chromosome 14, - strand):

1   aggaaagaag ccattttgtt aggctatatt aagcaatctg taaatgtaaa gtaattaaat
61  taatttattg attcagcaag tattcattcc tcttctattt gctagatagc ttttctagaa
121 gagttaaatg tgtgatttca tgaagcttct attaaggaat aaagggcaat aataaagagt
181 agtagaattt gtaagtataa tatagttaga agaaaagaag caaagattaa cttagttaaa
241 tataaggaaa gttcactgga aacgtttttt ttttcagtgt gtcttatatt tatgggtctt
301 gaagattcta tacccaagca cattattcct tctgagaggc aaccatgaat gcagacacct
361 tactgaatat tttaccttta agcaggaatg taagtacttt tagggtaaat atttctagtt
421 ccttggtgtt cctttgggat ggcatggata gtaagagata tgaaaacttt acagtgcaac
481 acttaaaaac acattccatg accaccagtg tatacttttg aaa

Primer binding sites are underlined and the sequencing primers are highlighted; the mutated nucleotide is shown in red.