An Ig Transmembrane Domain Motif Improves the Function of TCRs Transduced in Human T Cells: Implications for Immunotherapy.

Adoptive transfer of T lymphocytes (ACT) engineered with T-cell receptors (TCRs) of known antitumor specificity is an effective therapeutic strategy. However, a major constraint of ACT is the unpredictable interference of the endogenous TCR α and ß chains in pairing of the transduced TCR. This effect reduces the efficacy of the genetically modified primary T cells and carries the risk of generating novel TCR reactivities with unintended functional consequences. Here, we show a powerful approach to overcome these limitations. We engineered TCR α and ß chains with mutations encompassing a conserved motif (FXXXFXXS) required to stabilize the pairing of immunoglobulin heavy chain transmembrane domains. Molecular modeling supported the preferential pairing of mutated TCR and impaired pairing between mutated and wild-type TCRs. Expression of the mutated TCR was similar to wild type and conferred the expected specificity. Fluorescence resonance energy transfer analysis in mouse splenocytes transduced with mutated or wild-type TCRs showed a higher proximity of the former over the latter. Importantly, we show that mutated TCRs effectively outcompete endogenous TCRs and improve in vitro antitumor cytotoxicity when expressed in ex vivo isolated human T cells. This approach should contribute to improving current protocols of anticancer immunetherapy protocols.

Evolution of the complement system C3 gene in Antarctic teleosts.

Notothenioidei are typical Antarctic teleosts evolved to adapt to the very low temperatures of the Antarctic seas. Aim of the present paper is to investigate sequence and structure of C3, the third component of the complement system of the notothenioid Trematomus bernacchii and Chionodraco hamatus. We determined the complete nucleotide sequence of two C3 isoforms of T. bernacchii and a single C3 isoform of C. hamatus. These sequences were aligned against other homologous teleost sequences to check for the presence of diversifying selection. Evidence for positive selection was observed in the evolutionary lineage of Antarctic teleost C3 sequences, especially in that of C. hamatus, the most recently diverged species. Adaptive selection affected numerous amino acid positions including three residues located in the anaphylatoxin domain. In an attempt to evaluate the link between sequence variants and specific structural features, we constructed molecular models of Antarctic teleost C3s, of their proteolytic fragments C3b and C3a, and of the corresponding molecules of the phylogenetically related temperate species Epinephelus coioides, using human crystallographic structures as templates. Subsequently, we compared dynamic features of these models by molecular dynamics simulations and found that the Antarctic C3s models show higher flexibility, which likely allows for more pronounced movements of both the TED domain in C3b and the carboxyl-terminal region of C3a. As such dynamic features are associated to positively selected sites, it appears that Antarctic teleost C3 molecules positively evolved toward an increased flexibility, to cope with low kinetic energy levels of the Antarctic marine environment.

The structure of the CD3 ζζ transmembrane dimer in POPC and raft-like lipid bilayer: a molecular dynamics study.

Plasma membrane lipids significantly affect assembly and activity of many signaling networks. The present work is aimed at analyzing, by molecular dynamics simulations, the structure and dynamics of the CD3 ζζ dimer in palmitoyl-oleoyl-phosphatidylcholine bilayer (POPC) and in POPC/cholesterol/sphingomyelin bilayer, which resembles the raft membrane microdomain supposed to be the site of the signal transducing machinery. Both POPC and raft-like environment produce significant alterations in structure and flexibility of the CD3 ζζ with respect to nuclear magnetic resonance (NMR) model: the dimer is more compact, its secondary structure is slightly less ordered, the arrangement of the Asp6 pair, which is important for binding to the Arg residue in the alpha chain of the T cell receptor (TCR), is stabilized by water molecules. Different interactions of charged residues with lipids at the lipid-cytoplasm boundary occur when the two environments are compared. Furthermore, in contrast to what is observed in POPC, in the raft-like environment correlated motions between transmembrane and cytoplasmic regions are observed. Altogether the data suggest that when the TCR complex resides in the raft domains, the CD3 ζζ dimer assumes a specific conformation probably necessary to the correct signal transduction.

Evolutionary analysis of Antarctic teleost Toll-like receptor 2.

In the present study we address the investigation of TLR2 evolutionary selection in two Antarctic teleosts, Trematomus bernacchii (Nototheniidae) and Chionodraco hamatus (Channichthyidae). The nucleotide sequence of TLR2 has been determined in both species, encoding 20 leucine-rich repeats (LRRs) in the extracellular region and a classical Toll/IL-1R (TIR) domain in the intracellular region. High expression level of T. bernacchii TLR2 was found in spleen and skin. Using different methods we identified six codons that underwent Darwinian selection while 20 were found to be negatively selected. Molecular models of C. hamatus and T. bernacchii TLR2 ectodomain as well as of the TIR domain were built by Homology Modeling. Molecular Dynamics simulations were performed in water for 15 ns. The sites under positive selection were residing on the convex side of the solenoid, four out of six were in a 35-residue-long region including the central/N-terminal domain boundary: two in the external loop of LRR11 and the other two in the LRR12 loop. This region has been demonstrated to be the functional site of ligand interaction in human TLR2 structure. Antarctic TLR2 models showed more flexibility than TLR2 from the temperate species Gasterosteus aculeatus. These results suggest that the selective pressure has shaped TLR2 molecule in such a way that increased its activity under the peculiar Antarctic environmental conditions.

Antarctic teleost immunoglobulins: more extreme, more interesting.

We have investigated the immunoglobulin molecule and the genes encoding it in teleosts living in the Antarctic seas at the constant temperature of -1.86 °C. The majority of Antarctic teleosts belong to the suborder Notothenioidei (Perciformes), which includes only a few non-Antarctic species. Twenty-one Antarctic and two non-Antarctic Notothenioid species were included in our studies. We sequenced immunoglobulin light chains in two species and µ heavy chains, partially or totally, in twenty species. In the case of heavy chain, genomic DNA and the cDNA encoding the secreted and the membrane form were analyzed. From one species, Trematomus bernacchii, a spleen cDNA library was constructed to evaluate the diversity of VH gene segments. T. bernacchii IgM, purified from the serum and bile, was characterized. Homology Modelling and Molecular Dynamics were used to determine the molecular structure of T. bernacchii and Chionodraco hamatus immunoglobulin domains. This paper sums up the previous results and broadens them with the addition of unpublished data.

An evolutionary conserved motif is responsible for immunoglobulin heavy chain packing in the B cell membrane.

All species of vertebrates synthesize immunoglobulin molecules, which differ in an number of aspects but also share a few common features responsible for their function, such as the presence of a transmembrane domain in the membrane bound form of the immunoglobulin heavy chain (IgTMD) that ensures communication with the signal transducing Igα-Igß peptides. We have analyzed the gene sequence encoding the IgTMD of different heavy chain isotypes of very distant species, from shark to mammals. The IgTMD sequences show a high degree of sequence identity and their encoding nucleotide sequences were shown to be subject to purifying selection at most sites. We have built molecular models of seven IgTMDs from different vertebrate species and have investigated the formation of homodimer in a palmitoyl oleoyl phosphatidylcholine (POPC) lipid bilayer by molecular dynamics simulations. We found that the conserved FXXXFXXS/TXXXS motif, never observed to date in protein transmembrane chains, is responsible for the two heavy chains association through two pairs of Phe-Phe hydrophobic interactions and two pairs of Ser/Thr-Ser/Ser hydrogen bonds. This interaction pattern, which stabilizes the dimer conformation in the lipid bilayer, was unique, being different from any other pattern identified in transmembrane helices to date.

Evolution of the Antarctic teleost immunoglobulin heavy chain gene.

Notothenioid teleosts underwent major modifications of their genome to adapt to the cooling of the Antarctic environment. In order to identify specific features of the Antarctic teleost immunoglobulin, transcripts encoding the constant region of the IgM heavy chain from 13 Antarctic and non-Antarctic notothenioid species were sequenced. The primary mRNA splicing for the membrane form was found to be atypical in the majority of Antarctic species, because it led to exclusion of two entire constant exons, and to inclusion of 39-nucleotide exons encoding an unusually long Extracellular Membrane-Proximal Domain (EMPD). Genomic DNA analysis revealed that each 39-nucleotide exon fell within a long sequence that was the reverse complement of an upstream region. Deduced amino acid sequence analysis lead to the identification of cysteine encoding codons in the 39-nucleotide exons, but not in the respective sequence counterpart, suggesting that these residues might play an important role in the folding of the EMPD.

Structure and dimerization of the teleost transmembrane immunoglobulin region.

The immune system cells express activating receptors, which consist of a dimeric ligand-binding molecule associated with a signal transducing dimer. The communication between the receptor partners depends primarily on the interactions between their membrane-embedded segments. In the B cell receptor (BCR) the sequence traversing the lipid bilayer of the immunoglobulin (IgTM) is highly conserved among species. We have investigated the association of the IgTM regions of the BCR of the Antarctic teleost Chionodraco hamatus. The nucleotide sequence of the entire immunoglobulin chain has been determined and the length, polarity, and structure of the IgTM region have been thoroughly analyzed. Structural models of the IgTM homodimer were also obtained by performing several MD simulations in a lipid bilayer using, as a starting model, two copies of the IgTM helix placed at various relative orientations and distances. Despite a certain degree of conformational heterogeneity, the predicted models of the IgTM homodimer display similar packing interfaces, characterized by a high degree of surface complementarity. The residues presumably responsible for the interaction and, consequently for the receptor stability have been identified in this manner.

Immunoglobulin light chain isotypes in the teleost Trematomus bernacchii.

Three immunoglobulin light chain (IgL) isotypes TrbeL1, TrbeL2, and TrbeL3 were identified in the Antarctic teleost Trematomus bernacchii by immunoscreening a cDNA expression library, and using RT-PCR, and 5' RACE. One of them was distinguished in two subisotypes TrbeL1A and TrbeL1B. Real-time PCR experiments showed that the different isotypes were expressed in similar ratios in the various tissues analyzed. Interestingly, the expression level of TrbeL1A isotype was very high in all tissues. Molecular models of the CH1-CL domain pairings were built and minimized for the different isotypes. Several differences were identified in the superimposable structures mainly in the loops. In addition, the isotype-specific residues determined a different distribution of the charges on the external CL domain surface. Phylogenetic trees of 43 isotype representative sequences of CL domain from teleost species, built by different methods, indicated that all teleost light chain isotypes are distributed into three groups. Furthermore, the split of the group IgL1 into two subgroups, one of them carrying a micro-satellite DNA insertion, may have occurred in the Acanthopterygean ancestor.