Activation of T and natural killer (NK) cells leads to the tyrosine phosphorylation of pp36 and to its association with several signaling molecules, including phospholipase Cγ-1 and Grb2. Microsequencing of peptides derived from purified rat pp36 protein led to the cloning, in rat and man, of cDNA encoding a T- and NK cell–specific protein with several putative Src homology 2 domain–binding motifs. A rabbit antiserum directed against a peptide sequence from the cloned rat molecule recognized tyrosine phosphorylated pp36 from pervanadate-treated rat thymocytes. When expressed in 293T human fibroblast cells and tyrosine-phosphorylated, pp36 associated with phospholipase Cγ-1 and Grb2. Studies with GST–Grb2 fusion proteins demonstrated that the association was specific for the Src homology 2 domain of Grb-2. Molecular cloning of the gene encoding pp36 should facilitate studies examining the role of this adaptor protein in proximal signaling events during T and NK cell activation.
Three classes of multigene family-encoded receptors enable NK cells to discriminate between polymorphic MHC class I molecules: Ly-49 homodimers, CD94/NKG2 heterodimers and the killer cell inhibitory receptors (KIR). Of these, CD94/NKG2 has been characterized in both rodents and humans. In contrast, Ly-49 family members have hitherto been found only in rodents, and KIR molecules only in the human. In this report, we describe a human cDNA, termed Ly-49L, that constitutes the first human member of the Ly-49 multi-gene family. Compared with rodent Ly-49 molecules, the Ly-49L sequence contains a premature stop codon and predicts a truncated protein that lacks the distal part of a C-terminal lectin domain. Evidence is presented that the premature stop codon results from incomplete excision of the intron between the first two lectin domain exons. Splice variants predicting a full-size Ly-49L protein were not detected. As demonstrated by Northern blot analysis, Ly-49L was transcribed by IL-2-activated NK cells, but not by freshly isolated B or T cells. PCR screening of a 22-clone yeast artificial chromosome contig localized the LY49L locus to the human NK gene complex on chromosome 12p12-p13. Southern blot analysis of genomic DNA showed a simple pattern with a full-length Ly-49L probe at low stringency hybridization conditions, suggesting that Ly-49L may be the only human member of the Ly-49 multigene family.
For parents, the experience of having an infant in the NICU is often psychologically traumatic. No parent can be fully prepared for the extreme stress and range of emotions of caring for a critically ill newborn. As health care providers familiar with the NICU, we thought that we understood the impact of the NICU on parents. But we were not prepared to see the children in our own families as NICU patients. Here are some of the lessons our NICU experience has taught us. We offer these lessons in the hope of helping health professionals consider a balanced view of the NICU’s impact on families.
Three classes of major histocompatibility (MHC) class I binding receptors on natural killer (NK) cells have so far been described: CD94/NKG2 heterodimeric receptors and killer cell inhibitory receptors in the human, and Ly-49 homodimers in rodents. CD94, NKG2 and Ly-49 belong to the C-type lectin superfamily. As yet, CD94 and NKG2 molecules have not been detected in rodents or Ly-49 in humans. It has therefore been proposed that the two receptors represent functional equivalents in these species. The present study describes the cDNA cloning of a novel rat gene encoding a protein of 179 amino acids, 54.2% identical to human CD94. The single-copy Cd94 gene is localized to the rat NK gene complex (NKC), within 50 kb from Nkrp2, between the Nkrp1 and Ly49 gene clusters. By Northern blot analysis, we showed that rat CD94 is selectively expressed by NK cells and a small subset of T cells, similar to the human orthologue. This expression is strain dependent, with high expression in DA NK cells and low in PVG NK cells. Evidence is presented that this difference is not due to receptor repertoire shaping by MHC-encoded ligands, but is controlled by genetic elements residing within the NKC. The identification of a rat CD94 orthologue suggests that NK cell populations utilize two different C-type lectin receptors for MHC class I molecules in parallel.
The gene for a rat NK lectin-like receptor (NKLLR), named NKR-P2, has been cloned and characterized. Sequence analysis shows that it represents the orthologue of human NKG2D and that the two molecules form a distinct NKLLR family, no more related to NKG2A/B, -C or -E than to other NKLLR families. Nkrp2 is a single-copy gene containing seven introns, mapping to the rat NK gene complex. Rat NKR-P2 differs from the human orthologue in that its cytoplasmic tail contains 13 additional amino acids, encoded by a separate exon. Splice variants lacking this exon were not detected in T cells or NK cells. NKR-P2 is strongly expressed by NK cells. In contrast to other NKLLR, it is also strongly expressed by resting thoracic duct CD4+ and CD8+ T cells, but not by thymocytes or other hemopoietic cells.
Two different lectin-like receptors for MHC class I molecules have so far been identified on natural killer (NK) cells, the Ly-49 homodimeric receptors in mice and the NKG2/CD94 heterodimeric receptors in humans. The recent identification of a rat CD94 orthologue implied that NK cell receptors equivalent to NKG2/CD94 also exist in rodents. Here we describe the cDNA cloning of two rat genes homologous to members of the human NKG2 multigene family. The deduced rat NKG2A protein contains a cytoplasmic immunoreceptor tyrosine-based inhibition motif (ITIM), whereas the cytoplasmic tail of rat NKG2C lacks ITIM. The genes map to the rat NK gene complex and are selectively expressed by NK cells. The expression is strain dependent, with high expression in DA and low in PVG NK cells, correlating with the expression of rat CD94. Ly-49 genes have previously been identified in the rat, and the existence of rat NKG2 genes in addition to a CD94 orthologue suggests that NK cell populations utilize different C-type lectin receptors for MHC class I molecules in parallel.
Three women speak of and analyse their abandonment by healthcare professionals in the past five years following their foetus' diagnosis of a genetic disorder during pregnancy.As educated women, we were bewildered by our medical care, or lack thereof. Following prenatal diagnostics of trisomy 13 or 18, we chose to continue our pregnancies. We understood that our babies would most likely die in utero or soon after birth.To enable ourselves to make informed choices, we sought information from the internet. Here, it was discovered that some babies with these trisomies can live contented, comfortable lives for many years. We considered this information as well as the anomalies of our unborn and planned accordingly.We did not want our babies to receive nonbeneficial, burdensome interventions, nor did we want them to suffer. Our hopes were not for a miracle but were much simpler: to meet and hold our babies and to be a family. Although our children, choices and outcomes are unique, we all hoped for time with our babies. We also all wished to be able to make informed decisions that respected the dignity of the fragile lives we carried. IN UTERO Pauline, mother of Liam (trisomy 18)'Your baby isn't going to live', my obstetrician commented as I sat behind the steering wheel. Although I felt comfortable with him, he supplied me with no information about trisomy 18.At my second ultrasound I found myself panicking over my lack of specialist support. Liam had numerous medical complications and no one had spoken to me about his care. Sadly, it was my obstetrician's lack of referral that left me feeling professionally abandoned.
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