Wall-associated receptor kinases (WAKs), a subfamily of receptor-like protein kinases (RLKs) found only in plants, consist of extracellular WAK-GUB and EGF domain, transmembrane domain, and intracellular kinase domain. WAKs and its homologs, known as WAK-likes (WAKLs), play diverse roles in plants. Some WAKs associate with pectin in plant cell wall and take part in the regulation of plant cell expansion and development, whereas some are involved in defense responses through various mechanisms. Although the roles of WAKs and WAKLs in plant interactions with fungal and bacterial pathogens have been well studied, their contribution to plant resistance against the oomycetes remains largely unknown. OPEL, an apoplastic effector from Phytophthora parasitica, can induce callose deposition, ROS production, and defense gene expression in Nicotiana tabacum (cv. Samsun-NN). Previous study based on transcriptome analysis found several NtWAKs and NtWAKLs were significantly induced by OPEL treatment. Here, we further characterized these genes to investigate their roles in plant immune responses toward OPEL and P. parasitica. Sequence analysis indicates most of these candidate genes contain predicted protein structure similar to that of typical WAKs. Phylogenetic analysis showed some of these NtWAKs are orthologous to AtWAKs from Arabidopsis thaliana, whereas others form distinct clades. Analysis by qRT-PCR demonstrated the induction of specific NtWAKs and NtWAKLs after OPEL treatment and P. parasitica inoculation, including NtWAKL14x1 and NtWAKL14x2. When overexpressed on Nicotiana benthamiana, NtWAKL14x1-GFP localized in the plasma membrane. Downregulation of NtWAKL14x1 and NtWAKL14x2 by cucumber mosaic virus (CMV)-mediated gene silencing compromised OPEL-induced callose deposition and cell death, whereas enhanced P. parasitica infection on Nicotiana tabacum (cv. Samsun-NN). These results indicate NtWAKL14x1 and NtWAKL14x2 function as positive regulators of plant defense response toward OPEL and P. parasitica. This is the first report of WAKL genes to participate in the plant-oomycete interaction. Further investigations are needed for better understanding of the underlying mechanism.