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The DNA storage channel is considered, in which $M$ Deoxyribonucleic acid (DNA) molecules comprising each codeword, are stored without order, then sampled $N$ times with replacement, and the sequenced over a discrete memoryless channel. For a constant coverage depth $M/N$ and molecule length scaling $\Theta(\log M)$, lower (achievability) and upper (converse) bounds on the capacity of the channel, as well as a lower (achievability) bound on the reliability function of the channel are provided. Both the lower and upper bounds on the capacity generalize a bound which was previously known to hold only for the binary symmetric sequencing channel, and only under certain restrictions on the molecule length scaling and the crossover probability parameters. When specified to binary symmetric sequencing channel, these restrictions are completely removed for the lower bound and are significantly relaxed for the upper bound. The lower bound on the reliability function is achieved under a universal decoder, and reveals that the dominant error event is that of outage -- the event in which the capacity of the channel induced by the DNA molecule sampling operation does not support the target rate.