W. John Haynes scite author profile

Maternal microchimerism (MMc) has been associated with development of allospecific transplant tolerance, antitumor immunity, and cross-generational reproductive fitness, but its mode of action is unknown. We found in a murine model that MMc caused exposure to the noninherited maternal antigens in all offspring, but in some, MMc magnitude was enough to cause membrane alloantigen acquisition (mAAQ; "cross-dressing") of host dendritic cells (DCs). Extracellular vesicle (EV)-enriched serum fractions from mAAQ + , but not from non-mAAQ, mice reproduced the DC crossdressing phenomenon in vitro. In vivo, mAAQ was associated with increased expression of immune modulators PD-L1 (programmed death-ligand 1) and CD86 by myeloid DCs (mDCs) and decreased presentation of allopeptide+self-MHC complexes, along with increased PD-L1, on plasmacytoid DCs (pDCs). Remarkably, both serum EV-enriched fractions and membrane microdomains containing the acquired MHC alloantigens included CD86, but completely excluded PD-L1. In contrast, EV-enriched fractions and microdomains containing allopeptide+self-MHC did not exclude PD-L1. Adoptive transfer of allospecific transgenic CD4 T cells revealed a "split tolerance" status in mAAQ + mice: T cells recognizing intact acquired MHC alloantigens proliferated, whereas those responding to allopeptide+self-MHC did not. Using isolated pDCs and mDCs for in vitro culture with allopeptide+self-MHC-specific CD4 T cells, we could replicate their normal activation in non-mAAQ mice, and PD-L1-dependent anergy in mAAQ + hosts. We propose that EVs provide a physiologic link between microchimerism and split tolerance, with implications for tumor immunity, transplantation, autoimmunity, and reproductive success.

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Prokaryotic K⁺channels: From crystal structures to diversity

Kuo

et al. 2005

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The deep roots and wide branches of the K(+)-channel family are evident from genome surveys and laboratory experimentation. K(+)-channel genes are widespread and found in nearly all the free-living bacteria, archaea and eukarya. The conservation of basic structures and mechanisms such as the K(+) filter, the gate, and some of the gate's regulatory domains have allowed general insights on animal K(+) channels to be gained from crystal structures of prokaryotic channels. Since microbes are the great majority of life's diversity, it is not surprising that microbial genomes reveal structural motifs beyond those found in animals. There are open-reading frames that encode K(+)-channel subunits with unconventional filter sequences, or regulatory domains of different sizes and numbers not previously known. Parasitic or symbiotic bacteria tend not to have K(+) channels, while those showing lifestyle versatility often have more than one K(+)-channel gene. It is speculated that prokaryotic K(+) channels function to allow adaptation to environmental and metabolic changes, although the actual roles of these channels in prokaryotes are not yet known. Unlike enzymes in basic metabolism, K(+) channel, though evolved early, appear to play more diverse roles than revealed by animal research. Finding and sorting out these roles will be the goal and challenge of the near future.

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Yeast screens show aromatic residues at the end of the sixth helix anchor transient receptor potential channel gate

Zhou¹,

Su²,

Anishkin

et al. 2007

Proc. Natl. Acad. Sci. U.S.A.

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Transient receptor potential (TRP) channels are first elements in sensing chemicals, heat, and force and are widespread among protists and fungi as well as animals. Despite their importance, the arrangement and roles of the amino acids that constitute the TRP channel gate are unknown. The yeast TRPY1 is activated in vivo by osmotically induced vacuolar membrane deformation and by cytoplasmic Ca 2؉ . After a random mutagenesis, we isolated TRPY1 mutants that responded more strongly to mild osmotic upshocks. One such gain-of-function mutant has a Y458H substitution at the C terminus of the predicted sixth transmembrane helix. Direct patch-clamp examination of vacuolar membranes showed that Y458H channels were already active with little stimulus and showed marked flickers between the open and intraburst closed states. They remained responsive to membrane stretch force and to Ca 2؉ , indicating primary defects in the gate region but not in the sensing of gating principles. None of the other 18 amino acid replacements engineered here showed normal channel kinetics except the two aromatic substitutions, Y458F and Y458W. The Y458 of TRPY1 has its aromatic counterpart in mammalian TRPM. Furthermore, conserved aromatics one ␣-helical turn downstream from this point are also found in animal TRPC, TRPN, TRPP, and TRPML, suggesting that gate anchoring with aromatics may be common among many TRP channels. The possible roles of aromatics at the end of the sixth transmembrane helix are discussed.aromatic residue anchoring ͉ gating machinery ͉ mechanosensitivity ͉ yeast calcium signal ͉ vacuolar membrane T he transient receptor potential (TRP) superfamily encompasses a diverse group of nonspecific cation channels, each responding to multiple stimuli (1). Sequence similarity among all members of the TRP superfamily is limited to only the fifth transmembrane helix (TM5) through the sixth transmembrane helix (TM6). Comparisons therein show that animal TRP subtypes are no more related to each other than they are to fungal or protist TRP subtypes. TRPY1, the sole TRP homolog in the budding yeast Saccharomyces cerevisiae, forms a stretchactivated cation channel of 320-pS conductance that is located in the vacuolar membrane (2-4). Osmotic upshocks activate TRPY1 to release Ca 2ϩ to the cytoplasm (4). The released Ca 2ϩ further activates TRPY1 in a Ca 2ϩ -induced Ca 2ϩ release (CICR) feedback (2) and can be monitored by the luminescence of transgenic aequorin as a phenotype (4), which is valuable in mutant screening. Furthermore, the TRP channels on the yeast vacuole can be directly examined in situ under a patch clamp (2, 3, 5). In contrast, animal TRP channels in complex organs and tissues are often difficult to access. Patch-clamp examinations of animal TRP channels, when possible, are carried out heterologously, except for TRPC1 (6). To complement this effort, using animal models, we combined molecular genetics and patchclamp electrophysiology to analyze the structure-function relationship of yeast TRP channels. ResultsMutant Scre...

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Induction of Antibiotic Resistance in Paramecium tetraurelia by the Bacterial Gene APH‐3'‐II

Haynes

Ling

Saimi

et al. 1995

J Eukaryotic Microbiology

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We have generated a transformation marker for Paramecium using a Paramecium expression vector (pPXV) and the open reading frame (ORF) of the bacterial antibiotic resistance gene aminoglycoside 3'-phosphotransferase-II (APH-3'-II or neor) from the transposon Tn5. The expression vector contained a small multiple cloning site between the 5' and 3' non-coding regions of the calmodulin gene, and Tetrahymena telomere sequences for the stability of the plasmid in Paramecium. After the neor ORF was inserted, the plasmid was referred to as pPXV-NEO. Delivery of approximately 10-20 picoliters of linearized PXV-NEO at > or = 2000 copies/pl into the macronucleus effected 100% transformation. Southern and Northern blot hybridization showed the presence of neor-specific DNA and RNA, respectively, in all of the transformed clones but not in the untransformed clones. The degree of resistance to G-418, and the concentrations of neor-specific DNA and neor-specific RNA in the clones were proportional to the concentration of the vector injected. We have demonstrated that when the linearized plasmid was injected into the macronucleus, the prokaryotic sequence conferred an antibiotic resistance to Paramecium despite codon-usage differences.

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Yeast gain-of-function mutations reveal structure–function relationships conserved among different subfamilies of transient receptor potential channels

Su¹,

Zhou²,

Haynes³

et al. 2007

Proc. Natl. Acad. Sci. U.S.A.

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W. John Haynes

Modification of host dendritic cells by microchimerism-derived extracellular vesicles generates split tolerance

Prokaryotic K⁺channels: From crystal structures to diversity

Yeast screens show aromatic residues at the end of the sixth helix anchor transient receptor potential channel gate

Induction of Antibiotic Resistance in Paramecium tetraurelia by the Bacterial Gene APH‐3'‐II

Yeast gain-of-function mutations reveal structure–function relationships conserved among different subfamilies of transient receptor potential channels

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W. John Haynes

Modification of host dendritic cells by microchimerism-derived extracellular vesicles generates split tolerance

Prokaryotic K+channels: From crystal structures to diversity

Yeast screens show aromatic residues at the end of the sixth helix anchor transient receptor potential channel gate

Induction of Antibiotic Resistance in Paramecium tetraurelia by the Bacterial Gene APH‐3'‐II

Yeast gain-of-function mutations reveal structure–function relationships conserved among different subfamilies of transient receptor potential channels

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Prokaryotic K⁺channels: From crystal structures to diversity