Fly stocks were reared in bottles at 24oC. Flies were collected immediately after eclosion and aged for 29 days. Males were selected then frozen on dry ice.
Frozen samples were homogenized and extracted using the TRIzol reagent protocol (Invitrogen). RNA was purified on an RNeasy spin column (Qiagen), and DNase treated. Polyadenylated RNAs were purified from total RNA extracts via oligo(dT) binding, using standard Illumina protocol. The poly(A)+ RNA was fragmented using divalent cations under elevated temperature, following by first and second strand cDNA synthesis primed with random hexamers. The cDNA fragments were end-repaired using T4 DNA polymerase and Klenow DNA polymerase, and phosphorylated at their 5' ends with T4 polynucleotide kinase. After adding A bases to the 3' end of the DNA fragments, Illumina adaptor oligonucleotides were ligated to the ends and ~ 300 bp fragments were isolated from an agarose gel, enriched by PCR amplification, and gel-purified again.
Read length (bases):76
The samples were quantitated using a Nanodrop, and loaded onto a flow cell for cluster generation and sequenced on an Illumina Genome Analyzer II using either single read or paired end protocols (Illumina).
Reads were aligned to Dmel_Release_6 using the STAR aligner v2.3.0e (Linux x86_64) with default parameters on the FASTQ files to generate multiply-mapped BAM files. These were filtered to include reads with only 1 aligned hit ( NH:i:1 attribute) to generate uniquely-mapped BAM files. A custom script was used to convert BAM files into bedgraph files (bam2bedgraph.cc).
Note that for each pair of paired-end reads, the two reads were mapped independently, and only those reads mapping uniquely to the genome were included in the data submission to FlyBase. In other words, information from one read was not used to resolve ambiguous mapping of its paired read.
The RNA-seq profiles displayed by FlyBase in GBrowse and used for RPKM calculation can be accessed at the FTP link below as .wig files. Please take note of how these FlyBase .wig files represent data for a contiguous sequence of bases with the same signal value. The value is declared only for the first position of that region, and applies to all positions that follow (these are not explicitly listed) until a new value at a new base position is declared.