Generation and characterization of floxed and deleted LRRK1 and LRRK2 alleles
(A) Schematic illustrations of human LRRK1 and LRRK2 proteins showing similar functional domains. LRRK12015 protein is derived from exons 2-34 (Ensembl Genome Database: ENSG00000154237). LRRK22527 protein is derived from exons 1-51 (ENSG00000188906). LRR: Leucine rich repeats; Roc: Ras-of-complex; COR: C-terminal of Roc; KIN: Kinase domain.
(B) Schematic illustrations of the gene structures of mouse LRRK1 and LRRK2. The boxes in blue are exons that encode the LRRK1 and LRRK2 proteins, and the gray boxes represent the 5’ and 3’ UTRs. The exons are not drawn in scale. The start codon ATG is in exon 2 of LRRK1 and exon 1 of LRRK2. The exons 27-29 of LRRK1 and the promoter/exons 1-2 of LRRK2 are flanked with loxP sites (green arrowheads).
(C) Targeting strategy for the generation of the targeted, floxed, and deleted LRRK1 alleles. The red boxes represent the targeted exons 27-29, and the blue boxes represent the untargeted exons. The locations and sizes of the 5’ and 3’ external probes are shown. The targeting vector contains the 5’ and 3’ homologous regions (marked by dashed lines) and the middle region (from intron 26 to intron 29), which includes a loxP site (green arrowhead) in intron 26 (1,288 bp upstream of exon 27) and the PGK-neo selection cassette flanked by two FRT (FLP recognition target) sequences (gray circles) followed by another loxP site in intron 29 (1,023 bp downstream of exon 29). A negative selection cassette encoding diphtheria toxin fragment A (DTA) is also included in the targeting vector to reduce ES cells bearing randomly inserted targeting vectors. ES cells carrying the correctly targeted LRRK1 allele were transfected with pCAG-FLP to remove the PGK-neo cassette and generate the floxed LRRK1 allele. Floxed LRRK1 mice were bred with CMV-Cre transgenic mice to generate germline deleted LRRK1 mice. Detailed strategy for generating targeting vector and DNA sequence of floxed LRRK1 allele can be found in Figure 1-figure supplement 1 and 2, respectively.
(D) Southern analysis of the targeted and floxed LRRK1 alleles. Genomic DNA from ES cells or mouse tails was digested with HindIII and hybridized with the 5’ or 3’ external probe. For the 5’ probe, the resulting 17.0 kb and 4.8 kb bands represent the wild-type (WT) and the targeted (T) or floxed (F) alleles, respectively. For the 3’ probe, the resulting 17.0 kb and 12.2 kb bands represent the WT and the floxed alleles, respectively. Detailed Southern strategy can be found in Figure 1-figure supplement 3.
(E) Targeting strategy for the generation of the targeted, floxed, and deleted LRRK2 alleles. The red boxes represent LRRK2 exons 1 and 2, and the start codon ATG resides in exon 1. The locations and sizes of the 5’ and 3’ external probes are shown. The targeting vector contains the 5’ and 3’ homologous regions (marked by dashed lines) and the middle region (from the promoter to intron 2), which includes a loxP site (green arrowhead) upstream (1,768 bp) of the transcription initiation site and the PGK-neo selection cassette flanked by two FRT sequences (gray circles) and two loxP sites (green arrowheads) in intron 2 (878 bp downstream of exon 2). A negative selection cassette encoding DTA is also included in the targeting vector. Mice carrying the correctly targeted LRRK2 allele were crossed with Actin-FLP deleter mice to generate floxed LRRK2 mice, which were bred with CMV-Cre transgenic mice to generate germline deleted LRRK2 mice. Detailed strategy for generating targeting vector and DNA sequence of floxed LRRK2 allele can be found in Figure 1-figure supplement 4 and 5, respectively.
(F) Southern analysis of the targeted and floxed LRRK2 alleles. Genomic DNA from ES cells or mouse tails was digested with NheI and hybridized with the 5’ or 3’ external probe. For the 5’ probe, the resulting 11.5 kb and 3.6 kb bands represent the wild-type (WT) and the targeted (T) or floxed (F) alleles, respectively. For the 3’ probe, the resulting 11.5 kb and 5.2 kb bands represent the WT and the floxed alleles, respectively. Detailed Southern strategy can be found in Figure 1-figure supplement 6.
(G) Northern analysis of poly(A)+ RNA prepared from the lung of mice carrying homozygous germline deleted (11/11) LRRK1 alleles derived from the floxed LRRK1 alleles using the cDNA probe of exons 2-3 (left) and exons 27-29 (right). Using the upstream exons 2-3 probe, the LRRK1 transcripts in wild-type mice are the expected size of ∼7.4 kb, whereas the detected LRRK1 transcripts in LRRK1 11/11 mice are truncated, consistent with the deletion of exons 27-29 (625 bp), which results in a frameshift, and are expressed at lower levels, likely due to nonsense mediated degradation of the truncated LRRK1 mRNA. Using a probe specific for exons 27-29, there is no LRRK1 transcript in LRRK1 11/11 mice, as expected. Both blots were hybridized with a GAPDH probe as loading controls. Detailed Northern strategy and full-size blots are included in Figure 1-figure supplement 7 and 8, respectively. Extensive RT-PCR analysis of LRRK1 transcripts in 11/11 mice are shown in Figure 1-figure supplement 9.
(H) Northern analysis of total RNA prepared from the neocortex of mice carrying homozygous germline LRRK2 deleted (11/11) alleles using the cDNA probe of exons 1-5 shows the absence of LRRK2 transcripts. The blot was hybridized with a GAPDH probe as a loading control. The full-size blot is included in Figure 1-figure supplement 10. RT-PCR analysis of LRRK2 transcripts in 11/11 mice are shown in Figure 1-figure supplement 11
(I) Left: Western analysis of wild-type (+/+) and homozygous LRRK1 11/11 brains show the absence of LRRK1 protein. Right: Western analysis of the neocortex of wild-type (+/+) and homozygous LRRK2 11/11 mice shows the absence of LRRK2 protein. Vinculin was used as a loading control. Full-size blots can be found in Figure 1-Source Data 1.