Recently global warming is threatening the crop yield. It becomes a critical issue to improve tolerance of rice to harsh environment as well as crop yield. Rice (Oryza sativa) is one of the most important crops in the world and feeds nearly 50% of the world’s population. Besides, it can be a model plant for providing insights into gene functions of monocotyledonous plants. Based on our previous data, we found that rice class I small heat shock proteins (sHSP-CIs) selectively expressed during seed maturation (OsHSP16.9A) and Cu or Cd treatment (OsHSP18.0). To further characterize physiological function of sHSP-CIs, we constructed two transgenic rice plants constitutively overexpressing OsHSP16.9A (OsHSP16.9A-OE) and OsHSP18.0 (OsHSP18.0-OE) and three transgenic rice plants repressing OsHSP16.9A (Oshsp16.9A-RNAi), OsHSP18.0 (Oshsp18.0-RNAi), and sHSPs (Osshsp-RNAi). Our results indicated that Oshsp16.9A-OE seeds and seedlings and Oshsp18.0-OE seedlings had higher thermotolerance than wild type during heat stress. Besides, Osshsp-RNAi plants were sensitive to heat stress. Interesting, gain- and loss-of-function analyses identified that sHSPs involved in rice growth and development. Osshsp-RNAi plants were shown increased in tiller number and delayed in growth. These results suggest that sHSPs can not only function as chaperone to protect denatured proteins but also involve in rice growth process. Furthermore, OsHSP18.0-OE plants showed more resistance than OsHSP16.9A-OE and wild-type plants under Cu and Cd treatment. Similarly, OsHSP18.0-OE plants were less oxidative damage. In addition, OsHSP18.0-OE plants reduced Cu-induced membrane damage. These results indicated OsHSP18.0-OE play important role in heavy metal stress.