Project description:Kinesin-1 drives the movement of diverse cargoes, and it has been proposed that specific kinesin light chain (KLC) isoforms target kinesin-1 to these different structures. Here, we test this hypothesis using two in vitro motility assays, which reconstitute the movement of rough endoplasmic reticulum (RER) and vesicles present in a Golgi membrane fraction. We generated GST-tagged fusion proteins of KLC1B and KLC1D that included the tetratricopeptide repeat domain and the variable C-terminus. We find that preincubation of RER with KLC1B inhibits RER motility, whereas KLC1D does not. In contrast, Golgi fraction vesicle movement is inhibited by KLC1D but not KLC1B reagents. Both RER and vesicle movement is inhibited by preincubation with the GST-tagged C-terminal domain of ubiquitous kinesin heavy chain (uKHC), which binds to the N-terminal domain of uKHC and alters its interaction with microtubules. We propose that although the TRR domains are required for cargo binding, it is the variable C-terminal region of KLCs that are vital for targeting kinesin-1 to different cellular structures.

Project description:Each B-cell receptor consists of a pair of heavy and light chains. High-throughput sequencing can identify large numbers of heavy- and light-chain variable regions (V(H) and V(L)) in a given B-cell repertoire, but information about endogenous pairing of heavy and light chains is lost after bulk lysis of B-cell populations. Here we describe a way to retain this pairing information. In our approach, single B cells (>5 × 10(4) capacity per experiment) are deposited in a high-density microwell plate (125 pl/well) and lysed in situ. mRNA is then captured on magnetic beads, reverse transcribed and amplified by emulsion V(H):V(L) linkage PCR. The linked transcripts are analyzed by Illumina high-throughput sequencing. We validated the fidelity of V(H):V(L) pairs identified by this approach and used the method to sequence the repertoire of three human cell subsets-peripheral blood IgG(+) B cells, peripheral plasmablasts isolated after tetanus toxoid immunization and memory B cells isolated after seasonal influenza vaccination.

Project description:Existing methods for paired antibody heavy- and light-chain repertoire sequencing rely on specialized equipment and are limited by their commercial availability and high costs. Here, we report a novel simple and cost-effective emulsion-based single-cell paired antibody repertoire sequencing method that employs only basic laboratory equipment. We performed a proof-of-concept using mixed mouse hybridoma cells and we also showed that our method can be used for discovery of novel antigen-specific monoclonal antibodies by sequencing human CD19+ B cell IgM and IgG repertoires isolated from peripheral whole blood before and seven days after Td (Tetanus toxoid/Diphtheria toxoid) booster immunization. We anticipate broad applicability of our method for providing insights into adaptive immune responses associated with various diseases, vaccinations, and cancer immunotherapies.

Project description:Determination of expression levels of light chain V genes in peripheral blood B cells after FACS sorting for two populations of B cells (CD20+CD138-IgKappa+IgLambda- and CD20+CD138-IgKappa-IgLambda+). Analysis was performed on healthy individuals and SLE patients with analysis performed using several models.

Project description:Determination of expression levels of light chain V genes in peripheral blood B cells after FACS sorting for two populations of B cells (CD20+CD138-IgKappa+IgLambda- and CD20+CD138-IgKappa-IgLambda+). Analysis was performed on healthy individuals and SLE patients with analysis performed using several models. Dual channel hybridization with experimental samples detected on red channel and reference sample detected on green channel. Two replicate hybridizations.

Project description: Not available

Project description:Cytoplasmic dynein is a microtubule-based motor protein complex that plays important roles in a wide range of fundamental cellular processes, including vesicular transport, mitosis, and cell migration. A single major form of cytoplasmic dynein associates with membranous organelles, mitotic kinetochores, the mitotic and migratory cell cortex, centrosomes, and mRNA complexes. The ability of cytoplasmic dynein to recognize such diverse forms of cargo is thought to be associated with its several accessory subunits, which reside at the base of the molecule. The dynein light chains (LCs) LC8 and TcTex1 form a subcomplex with dynein intermediate chains, and they also interact with numerous protein and ribonucleoprotein partners. This observation has led to the hypothesis that these subunits serve to tether cargo to the dynein motor. Here, we present the structure and a thermodynamic analysis of a complex of LC8 and TcTex1 associated with their intermediate chain scaffold. The intermediate chains effectively block the major putative cargo binding sites within the light chains. These data suggest that, in the dynein complex, the LCs do not bind cargo, in apparent disagreement with a role for LCs in dynein cargo binding interactions.

Project description:B cells reactive toward phosphatidylcholine (PtC) are enriched in the B1 B cell subset, and express predominantly one of two VH/Vk combinations to confer this specificity: VH12/Vk4/5H and VH11/Vk9. Studies of transgenic mice expressing the VH12 heavy chain (VH12 mice) suggest two major checkpoints for light chain expression in this system: the first involves selection of V-J rearrangements which encode a “permissive” light chain that can functionally pair with the VH12 heavy chain; the second involves receptor editing to salvage non-PtC reactive B cells to acquire a permissive light chain that confers PtC reactivity. If this model is correct, impairing receptor editing should reduce the frequency of PtC-reactive B1 B cells in VH12 mice. To test this possibility, we bred VH12 mice to transgenic mice expressing a catalytically inactive form of RAG1 (dnRAG1 mice) which show a defect in receptor editing. Interestingly, dnRAG1 expression in VH12 mice enforces development of PtC-reactive B1 B cells, rescuing the loss of splenic B cells observed in VH12 mice. These data suggest receptor editing normally functions to remove a large portion of PtC-specific B cells in VH12 mice. Deep sequencing of the expressed light chain repertoire of PtC-reactive and non-reactive B cells in VH12 mice revealed that PtC-reactive B cells predominantly expressed the Vk4/5H (IGKV4-91) light chain gene, whereas PtC-non-reactive B cells expressed a broader, yet restricted, set of light chain genes. This analysis also revealed a low frequency of in-frame hybrid light chain genes appearing to originate via Type 2 gene replacement, which we show can originate from template switching during PCR.

Project description:Collagen plays a fundamental role in all known metazoans. In collagens three polypeptides form a unique triple-helical structure with a one-residue stagger to fit every third glycine residue in the inner core without disturbing the poly-proline type II helical conformation of each chain. There are homo- and hetero-trimeric types of collagen consisting of one, two or three distinct chains. Thus there must be mechanisms that control composition and stagger during collagen folding. Here, we uncover the structural basis for both chain selection and stagger formation of a collagen molecule. Three distinct chains (?1, ?2 and ?3) of the non-collagenous domain 2 (NC2) of type IX collagen are assembled to guide triple-helical sequences in the leading, middle and trailing positions. This unique domain opens the door for generating any fragment of collagen in its native composition and stagger.

Project description:Immunoglobulin light chain amyloidosis is the most common form of systemic amyloidosis. AL amyloidosis is caused by a misfolded light chain produced by a clonal population of plasma cells. Disease status currently is defined by measuring the absolute quantity of serum free light chain protein, but this measurement often fails to identify the subclinical presence of clonal cells that may merit additional therapy. Next generation sequencing has the sensitivity to measure the relative amount of dominating light chains within the repertoire of a patient, and this technique is in clinical use to identify clonal populations of plasma cells for multiple myeloma, a related disorder. In this proof-of-concept study, we used bone marrow aspirates of AL amyloidosis positive patients and used reverse transcription of the antibody transcriptome followed by next generation sequencing to identify antibody variable-diversity-joining gene sequences for patients with immunoglobulin light chain amyloidosis, and demonstrate that this technology can be used to identify the dominant clone. The data also reveal differing patterns of overall antibody repertoire disruption in different patients. This method merits further study in larger prospective studies to establish its utility in detecting residual disease for patients with immunoglobulin light chain amyloidosis.