20 research outputs found
Creating huV<sub>H</sub> diversity by gene conversion using a human heavy chain pseudogene array with fully synthetic CDRs.
<p>The chicken V<sub>H</sub> was replaced by a huV<sub>H</sub> including 7 human pseudogenes with fully synthetic CDR sequences (the SynVH-A7 array). The inserted huV<sub>H</sub> had a stop codon and a HpaI restriction enzyme site in CDR3 so that there was no IgM expression unless the stop codon was repaired due to gene conversion. DT40 cells were cultured for four weeks after insertion and afterwards analyzed by sequencing for possible gene conversion events, deletions and point mutations. Gene conversion events for the stop in CDR3 are shown. The length of the line showing the gene conversion events corresponds with the actual length of the gene conversion event observed. Frequency of every event is shown in bold. Every change in the parental sequence was counted as individual event.</p
Expression and signaling in DT40 cells with immunoglobulin knockouts and chimeric immunoglobulin insertions.
<p>Wild-type cells (DT40 wt), V<sub>L</sub> knockout (<i>Igl<sup>KO</sup></i>), V<sub>H</sub> knockout (<i>Igh<sup>KO</sup></i>) and V<sub>L</sub>-V<sub>H</sub> double knockout cells (<i>Igl<sup>KO</sup>, Igh<sup>KO</sup></i>) as well as huV<sub>K</sub> insertion (<i>Igl<sup>huVK</sup></i>), huV<sub>H</sub> insertion (<i>Igh<sup>huVH</sup></i>) and huV<sub>K</sub>-huV<sub>H</sub> (<i>Igl<sup>huVK</sup>, Igh<sup>huVH</sup></i>) double insertion cell lines were analyzed for expression and signaling of immunoglobulin receptors. a) 1×10<sup>6</sup> cells were lysed and immunoglobulin heavy chain expression determined by Western blotting using goat-anti-chicken-IgM-AP and immunoglobulin light chain expression by rabbit-anti-chicken-IgY-AP. Mouse-anti-β-actin followed by goat-anti-mouse-AP was used to detect β-actin. b) The cell lines from above and <i>Igl<sup>huVK</sup></i> cells with a stop codon (<i>Igl<sup>huVK-Stop</sup></i>) in CDR1 cultured for four weeks were stained with mouse-anti-chicken-IgM followed by goat-anti-mouse-Ig-Cy5. All cell lines except wild type express eGFP from the selectable marker cassette used in the knockouts. Fluorescence signal was visualized using a Beckman Coulter FC-500. c) 1×10<sup>6</sup> wild type DT40 cells, non-green <i>Igl<sup>KO</sup>, Igh<sup>KO</sup></i> cells and non-green <i>Igl<sup>huVK</sup>, Igh<sup>huVH</sup></i> DT40 cells were labeled with FLUO-4-AM and incubated with 10 µg/ml goat-anti-chicken-IgM starting from the time point indicated by arrows. The change in fluorescence intensity was measured for a total of 300 sec using a Beckton Dickinson LSRII Fortessa. One of three representative experiments is shown. d) The same cell lines (DT40 wt grey, <i>Igl<sup>KO</sup>, Igh<sup>KO</sup></i> red, <i>Igl<sup>huVK</sup>, Igh<sup>huVH</sup></i> blue) were stained with goat-anti-human-kappa-RPE. Fluorescence was measured using a Beckman Coulter FC-500.</p
Creating huV<sub>K</sub> diversity by gene conversion using a human light chain pseudogene array with single amino acid changes in the CDRs.
<p>The chicken V<sub>L</sub> was replaced by a huV<sub>K</sub> including 12 human synthetic pseudogenes with single amino acid changes in the CDR sequences (the SynVK-12 array). The inserted huV<sub>K</sub> had a stop codon and a HpaI restriction enzyme site in CDR1 or CDR3 so that there was no IgM expression unless the stop codon was repaired due to gene conversion. DT40 cells were cultured for four weeks after insertion, and afterwards analyzed by sequencing for possible gene conversion events, deletions and point mutations. Gene conversion events for the stop in CDR1 are shown in a) and b). Gene conversion events for the stop in CDR3 are shown in c) and d). In diagrams a) and c), the length of the line showing the gene conversion events corresponds with the actual length of the gene conversion event observed, and the number above the line indicates the pseudogene name. Frequency of every event is shown in bold at left. The arrows under the pseudogenes and the functional V in c–d) show the orientation of the genes. Every change in the parental sequence was counted as an individual event.</p
Creating huV<sub>H</sub> diversity by gene conversion using a human heavy chain pseudogene array with single amino acid changes in the CDRs.
<p>The chicken V<sub>H</sub> was replaced by a huV<sub>H</sub> including 17 human synthetic pseudogenes with single amino acid changes in the CDR sequences (the SynVH-B array). The inserted huV<sub>H</sub> had a stop codon and a HpaI restriction enzyme site in CDR1 or CDR3 so that there was no IgM expression unless the stop codon was repaired due to gene conversion. DT40 cells were cultured for four weeks after insertion and afterwards analyzed by sequencing for possible gene conversion events, deletions and point mutations. Gene conversion events for the stop in CDR1 are shown in a) and b). Gene conversion events for the stop in CDR3 are shown in c). No pseudogene name is indicated over the line in CDR3 in c) because the sequences could have been derived from every pseudogene except 22 and 30. The length of the line showing the gene conversion events corresponds with the actual length of the gene conversion event observed. Frequency of every event is shown in bold. Every change in the parental sequence was counted as individual event.</p
Integrase-mediated insertion of human V<sub>L</sub> and V<sub>H</sub> to replace the corresponding chicken genes.
<p>The <i>Igl<sup>KO</sup></i> and <i>Igh<sup>KO</sup></i> cell lines, as well as the <i>Igl<sup>KO</sup>, Igh<sup>KO</sup></i> line, were used to insert human V<sub>K</sub> or V<sub>H</sub> into the chicken loci. Co-transfection of ΦC31 integrase and the shown a) huV<sub>K</sub> or b) huV<sub>H</sub> constructs resulted in recombination of the attP and attB sites leading to an insertion of the human V constructs and creating attL and attR sites. A β-actin promoter was integrated in front of the neomycin (neo) or blasticidin (Bsr) gene, and cells were selected with the indicated drug for stable integration of the huV<sub>K</sub> or huV<sub>H</sub>. In the case of huV<sub>K</sub> insertion into the chicken <i>Igl<sup>KO</sup></i> single knockout, the selectable marker cassette was the same as for the heavy chain locus shown in b). c) To test for proper integration of the human genes, genomic DNA was isolated and a construct-specific PCR was performed with the indicated primers (primers are indicated by black arrowheads with primer orientation: VK+VH 5′, primers 12 and 9; VK 5′ Bsr, primers 8 and 9; VK 3′, primers 10 and 11; VH 3′, primers 13 and 14). Primers are placed on the 5′ and 3′ side of the integration showing the correct integration versus the knock out or wild type DT40 cell lines. β-actin was used as a quality control for the genomic DNA. Scale bar equals 1 kb.</p
Alignment of the SynVH-B pseudogene array with functional huV<sub>H</sub>.
<p>The human SynVH-B pseudogenes SynVH21 to SynVH37 were aligned with functional huV<sub>H</sub> using Lasergene (DNAStar Inc.,Madison, USA). CDRs are marked by upright dashed lines. The arrow indicates position of the HpaI site and stop codon inserted in a) CDR1 or b) CDR3.</p
Creating huV<sub>K</sub> diversity by gene conversion using a human light chain pseudogene array with naturally occurring CDRs, AID optimization and framework changes.
<p>The chicken V<sub>L</sub> was replaced by a huV<sub>K</sub> including 16 human synthetic pseudogenes containing naturally occurring CDR sequences from an EST database (NCBI), the SynVK-C array. In addition the pseudogenes and the functional V<sub>L</sub> were AID optimized. Some of the pseudogenes also differ in their framework regions compared to the functional huV<sub>K</sub>. The inserted huV<sub>K</sub> had a stop codon and a HpaI restriction enzyme site in CDR1 or CDR3 so that there was no IgM expression unless the stop codon was repaired due to gene conversion. DT40 cells were cultured for four weeks after insertion and afterwards analyzed by sequencing for possible gene conversion events, deletions and point mutations. Gene conversion events for the stop in CDR1 are shown in a) and b). Gene conversion events for the stop in CDR3 are shown in c). The length of the line showing the gene conversion events corresponds with the actual length of the gene conversion event observed. Frequency of every event is shown in bold at left. The arrows under the pseudogenes and the functional V in b) show the orientation of the genes. Every change in the parental sequence was counted as individual event.</p
Alignment of the SynVK-C pseudogene array with functional huV<sub>K</sub>.
<p>The human SynVK-C pseudogenes SynVK20 to SynVK35 were aligned with functional huV<sub>K</sub> using Lasergene (DNAStar Inc.,Madison, USA). CDRs are marked by upright dashed lines. The arrow indicates the position of the HpaI site and stop codon inserted in a) CDR1 or b) CDR3.</p
Alignment of the SynVH-A7 pseudogene array with functional huV<sub>H</sub>.
<p>The human SynVH-A7 pseudogenes SynVH14 to SynVH20 were aligned with functional huV<sub>H</sub> using Lasergene (DNAStar Inc.,Madison, USA). CDRs are marked by upright dashed lines. The arrow indicates the position of the HpaI site and stop codon inserted in CDR3.</p
Alignment of the SynVK-12 pseudogene array with functional huV<sub>K</sub>.
<p>The human SynVK-12 pseudogenes SynVK1 to SynVK12 were aligned with functional huV<sub>K</sub> using Lasergene (DNAStar Inc.,Madison, USA). Complementarity determining regions (CDR) are marked by upright dashed lines. The arrow indicates the position of the HpaI site and stop codon inserted in a) CDR1 or b) CDR3.</p