The stable sedimentary nitrogen isotope compositions of bulk organic matter (δ¹⁵Nbulk) and the silicon isotope composition of diatoms (δ³⁰SiBSi) both mainly reflect the degree of past nutrient utilization by primary producers. However, in ocean areas where anoxic and suboxic conditions prevail, the δ¹⁵Nbulk signal ultimately recorded within the sediments is also influenced by water column denitrification, causing an increase in the subsurface δ¹⁵N signature of dissolved nitrate (δ¹⁵NO^-₃) upwelled to the surface. Such conditions are found in the oxygen minimum zone off the coast of Peru, where, at present, an increase in subsurface δ¹⁵NO-3 from north to south along the shelf is observed due to ongoing denitrification within the poleward-flowing subsurface waters, while the δ³⁰Si signature of silicic acid (δ³⁰Si.OH/4) at the same time remains unchanged. Here, we present three new δ³⁰SiBSi records between 11 and 15 S and compare these to previously published δ³⁰SiBSi and δ¹⁵Nbulk records from Peru covering the past 600 years. We present a new approach to calculate past subsurface δ¹⁵NO-3 signatures based on the direct comparison of δ³⁰SiBSi and δ¹⁵Nbulk signatures at a latitudinal resolution for different time periods. Our results show that, during the Current Warm Period (CWP, since 1800 CE) and prior shortterm arid events, source water δ¹⁵NO-3 compositions have been close to modern values, increasing southward from 7 to 10 ‰ (between 11 and 15 S). In contrast, during the Little Ice Age (LIA) we calculate low δ¹⁵NO-3 values between 6 ‰ and 7.5 ‰. Furthermore, the direct δ³⁰SiBSi versus δ¹⁵Nbulk comparison also enables us to relate the short-term variability in both isotope compositions to changes in the ratio of nutrients (NO-3 V Si.OH/4) taken up by different dominating phytoplankton groups (diatoms and non-siliceous phytoplankton) under the variable climatic conditions of the past 600 years. Accordingly, we estimate a shift from a 1 V 1 (or 1 V 2) ratio during the CWP and a 2 V 1 (up to 15 V 1) ratio during the LIA, associated with a shift from overall high nutrient utilization to NO^-₃-dominated (and thus non-siliceous phytoplankton) utilization.