Reading a scientific text is an major and important way of learning science concepts. Through reading, students comprehend the content of the scientific text, construct a mental models, and may apply it to a new situation. Self-regulated learning (SRL) is essential when learning through or solving complex tasks (e.g., science reading or problem-solving). Extant literature has shown that, although separately, calibration accuracy or quality of SRL strategies learners use would affect reading comprehension; however, the interrelationships among the three variables were unexplored. To address this gap, the aim of the study was to investigate how calibration accuracy may affect learners’ use of SRL strategies, which in turn influences their reading comprehension. A mix-method approach was used to explore non-biology majored college students’ calibration accuracy, SRL strategies, and reading comprehension when reading a biology text in a computer-based learning environment. Correlations among calibration accuracy, reading performance, and use of SRL strategies were first explored. Reading comprehension and frequencies of SRL strategies used within and across text paragraphs were then compared for students with high, moderate, or low calibration accuracy. Two case students from each calibration accuracy group were used to exemplify how SRL strategies unfolded during science reading would influence reading comprehension. The findings of correlation analyses revealed a significant positive correlation between calibration accuracy and reading comprehension. Students who deployed higher frequencies of “summarization”, “inference”, “re-reading” and “content evaluation”, exhibited better reading comprehension. Between-group comparisons indicated that no statistically significant differences were found on students’ use of cognitive and metacognitive strategies when reading within paragraphs. However, significant differences were found for inter-paragraph SRL strategies. Learners with better calibration accuracy used SRL strategies to comprehend sentences and paragraphs; they also utilized cognitive strategies such as “inference” and “summarization” to infer across paragraphs. At the meantime, they used metacognitive strategies such as using “feeling of knowing” and “judgment of learning” to evaluate inferences resulted from across-paragraph reasoning. On contrary, learners with poor calibration accuracy mainly used “inference”, “summarization”, “feeling of knowing”, and “judgment of learning” for reading within paragraphs rather than across paragraphs. Qualitative analyses for the case students supported the results of group comparisons and illustrated characteristics for dynamic uses of SRL strategies when reading within and across paragraphs. The findings of the study indicated that reading comprehension is influenced by frequencies of particular cognitive and metacognitive strategies; the timing and reading scale (within or across paragraphs) in which the students’ SRL strategies were activated would also affect their level of reading comprehension.